Seismic rocking effects on a mine tower under induced and natural earthquakes

Bońkowski, Piotr; Kuś, Juliusz; Zembaty, Zbigniew

doi:10.1007/s43452-021-00221-7

Cited by 4 publications

(7 citation statements)

References 26 publications

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“…, ω n are the cutting circular frequencies in the dispersion curve. To identify the participation factor 𝑁 𝑗 𝑚 , the energy flow density S𝑗 𝑚 naturally becomes the parameter to be prior determined, necessitating the determination of unknown free-field stresses and velocities as shown in Equations ( 16) and (19). For Rayleigh waves in the jth sublayer, the free-field velocities U𝑗 X (z, ω) and U𝑗 Z (z, ω) of the x = 0 cross-section can be easily acquired with the differential of the free-field displacements as…”

Section: Modal Participation Factormentioning

confidence: 99%

“…18 Bońkowski et al demonstrated the contribution of the Rayleigh waves to mine towers and suggested their involvement in future calibrations of the seismic codes. 19 Meza-Fajardo et al concluded that the rocking motions associated with Rayleigh waves can trigger dominant responses of SSI systems and should be a necessary consideration for the structural design. [20][21][22][23] Alielahi et al also recommended considering Rayleigh waves in the design of soil-cavity interaction.…”

Section: Introductionmentioning

confidence: 99%

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Multi‐mode inversion of dispersive surface‐wave free fields in layered media

Xue,

Dong,

et al. 2024

Earthq Engng Struct Dyn

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Inversion of surface‐wave free fields is of great importance in providing seismic excitations for the finite element (FE) analysis of soil–structure interaction (SSI) systems. In the case of layered media, the propagating surface waves are characterized by their unique dispersion property, resulting in dispersive multi‐mode surface wavefields. Available studies primarily focus on only the fundamental mode and neglect the influence of higher modes, which fail to identify the real structural response characteristics. To enhance the precision of seismic excitations for SSI systems situated in layered media, a multi‐mode inversion method for dispersive surface‐wave free fields is proposed in this study. The proposed method employs the energy flow density to characterize the participation volume of dispersive modes, and further calculates corresponding modal participation factors by combining with the dispersion curve and dynamic‐stiffness matrix (DSM) method. The modal participation factors are then utilized to assign the ground surface components of each mode and invert respective single‐mode surface‐wave free fields. Based on the mode superposition theory, all the single‐mode surface‐wave free fields are finally superimposed to construct the multi‐mode wavefields. The accuracy of the proposed method is thoroughly verified and validated across various types of layered media. Furthermore, the engineering application of the proposed method is illustrated by performing the FE analysis on an SSI example. The analysis results highlight the significant participation of surface waves' higher modes in structural seismic responses, particularly in the weak‐interbed type media.

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Section: Modal Participation Factormentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Multi‐mode inversion of dispersive surface‐wave free fields in layered media

Xue,

Dong,

et al. 2024

Earthq Engng Struct Dyn

View full text Add to dashboard Cite

show abstract

“…Moreover, some studies (e.g., Xia et al 2006; Yuen and Kuok 2010; Guéguen et al 2017;Astorga et al 2018) also con rmed the effects of environmental factors through mathematical statistical analyses. Other studies (e.g., Shan et al 2020;Bońkowski et al 2021) revealed a building's self-healing ability, where the building's resonant frequency drift due to earthquake events, environmental factors, or random forced vibrations could gradually return to its original level, although the recovery times of frequency drift could be considerably different with respect to different environmental factors.…”

Section: Introductionmentioning

confidence: 99%

“…found that the rotation rate derived from the translational array is smaller than that recorded by a rotational seismometer when the center of torsion is not located at the same location, which facilitates the judgment of the rotational center of the building. Bońkowski et al (2018Bońkowski et al ( , 2019Bońkowski et al ( , 2021 found that the bending moments of high slender towers are signi cantly affected by the rotational motion of the ground, although under a moderately intensive rotational earthquake. However, there are still many issues that need to be addressed, such as the characteristics of high-rise building rotation under environmental ambient noise and earthquakes and their differences and the impact of seismic rotational motion on asymmetric high-rise buildings.…”

Section: Introductionmentioning

confidence: 99%

Six-component seismic monitoring of a high-rise building

Qin

Wang

Chen

et al. 2023

Preprint

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We report seismic observations and studies on a high-rise building deployed with six-degree-of-freedom (6-DOF) seismometers. By analyzing the horizontal-to-vertical spectral ratios (HVSRs) of translational components, five resonant modes within 2 Hz are identified. By analyzing the improved rotational vertical-to-horizontal spectral ratios (RVHSRs) of rotational components, three torsional resonant modes are identified; two torsional resonant modes are consistent with those of the translational records, while the higher frequency mode is not observed in the translational motions. Continuous 6C seismic observations over 70 days indicate that the various resonant frequencies of high-rise buildings are related to multiple factors, such as human activity and rainfall levels. The most interesting phenomenon is that three translational resonant modes exhibit diurnal variations; two torsional resonant modes do not have the same trend as translational resonances, which indicates that the translational and torsional resonant modes of the building possibly have different physical mechanisms. In addition, analyses of ambient noises with the directional HVSR method and analyses of vibration caused by earthquakes commonly show that building vibration is directional; furthermore, there are nonpositive correlations of displacements between the middle and top floors of the high-rise building under multiple earthquake events. The nonlinear response of the high-rise building concerning the height is consistent with the responses reported in former studies.

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“…The large headframe is the core structure of a mine hoisting system, and also a highrise and hollow steel-framed building [1][2][3]. With the development of mine hoisting system towards large-scale, higher requirements are put on the structural design of the large headframe [4,5].…”

Section: Introductionmentioning

confidence: 99%

Dynamic Characteristic Analysis and Structural Optimization Design of the Large Mining Headframe

Liu

Huang

et al. 2022

Machines

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A large headframe is the core structure of a mine hoisting system. In the traditional design, only the static analysis under load is considered, resulting in the resonance phenomenon of the large headframe in later applications. In order to restrain the resonance phenomenon, a novel method for dynamic characteristic analysis and structural optimization design of a large headframe is proposed. First, the eigenfrequencies and vibration modes of the large headframe were obtained through modal analysis. The results showed that the numerical values of the multi-order eigenfrequencies of the system are relatively close. When subjected to alternating loads of similar frequencies, a large headframe is prone to the resonance phenomenon. Second, the steady-state vibration response of the large headframe was obtained through harmonic response analysis. The results showed that when the frequency of the alternating load is close to the first-order eigenfrequency, the vibration amplitude increases. Meanwhile, the fourth-order and the fifth-order eigenfrequencies are very close. When subjected to alternating loads of similar frequencies, the fourth-order and the fifth-order vibration modes of the headframe will be excited simultaneously. At this time, the headframe will have a strong resonance, which may cause structural damage and other problems. Finally, based on the above analysis, nine different structural optimization schemes are proposed in this paper. Through modal analysis and harmonic response analysis, the nine schemes were compared and analyzed, and the optimal scheme was eventually determined as scheme 9. The method proposed in this paper provides a new concept for the structural optimization design of a large mining headframe, and it has great significance for restraining the resonance phenomenon and ensuring the safety of mining operations.

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Seismic rocking effects on a mine tower under induced and natural earthquakes

Cited by 4 publications

References 26 publications

Multi‐mode inversion of dispersive surface‐wave free fields in layered media

Multi‐mode inversion of dispersive surface‐wave free fields in layered media

Six-component seismic monitoring of a high-rise building

Dynamic Characteristic Analysis and Structural Optimization Design of the Large Mining Headframe

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