Negative stiffness enhanced tuned mass damper (NS-TMD) for seismic induced response mitigation of isolated bridges

Seismic isolators have been extensively utilized in the field of structural vibration control due to their superior control effectiveness in reducing absolute acceleration responses. However, this effectiveness comes with a compromise on large isolation deformation, which may result in various issue...

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Published inEngineering structures Vol. 325; p. 119416
Main Authors Jiang, Shaodong, Ma, Ruisheng, Bi, Kaiming, Du, Xiuli, Song, Jian
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 15.02.2025
Subjects
Control performance
Earthquake ground motions
Isolated bridge
Multi-objective optimization
Negative stiffness enhanced tuned mass damper
Control performance
Isolated bridge
Multi-objective optimization
Negative stiffness enhanced tuned mass damper
Earthquake ground motions
Online AccessGet full text
ISSN0141-0296
DOI10.1016/j.engstruct.2024.119416

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Abstract Seismic isolators have been extensively utilized in the field of structural vibration control due to their superior control effectiveness in reducing absolute acceleration responses. However, this effectiveness comes with a compromise on large isolation deformation, which may result in various issues, such as pounding and/or unseating damages of bridge decks. To address these issues, a negative stiffness enhanced tuned mass damper (NS-TMD) was proposed, aiming to minimize absolute acceleration while simultaneously limiting isolation deformation, and its control effectiveness has been demonstrated. However, the previous studies primarily focused on single-objective optimization without considering NS-TMD stroke, and the conventional negative stiffness (NS) devices, e.g., the pre-compressed helical springs with revolute joints, could not be well compatible with NS-TMD due to limited operating range. To this end, this study proposes a novel NS-TMD, which consists of a TMD with a curved-type mass block and an NS element based on a cam-roller-spring (CRS) mechanism. The working mechanism of the novel NS-TMD is first introduced, and its mechanical model is formulated. This novel system is then applied to a typical isolated bridge to illustrate its control effectiveness. Equilibrium equations and state space formulations of the system are derived. Subsequently, parametric analysis on NS-TMD is performed, followed by the proposal of a multi-objective optimization strategy to simultaneously minimize the relative displacement of the bridge deck and the stroke of NS-TMD. Finally, the control performance of NS-TMD is systematically evaluated. Numerical results show that the optimized NS-TMD not only reduces the deck displacement of the bridge system (with a maximum reduction ratio of 49.50 %) but also decreases its absolute acceleration. Furthermore, NS-TMD can achieve superior control performance in terms of the deck displacement, while limiting the stroke within a reasonable range. In summary, NS-TMD is a highly efficient alternative to conventional TMDs in terms of control effectiveness and feasibility. [Display omitted] •The novel NS-TMD integrates a curved-type mass block with a CRS-based NS element.•A performance-based multi-objective optimization strategy for NS-TMD is developed.•Optimized NS-TMD simultaneously reduces both deck displacement and acceleration.•NS-TMD achieves superior control performance while limiting stroke within reasonable ranges.•NS-TMD surpasses conventional TMDs in control effectiveness.
AbstractList Seismic isolators have been extensively utilized in the field of structural vibration control due to their superior control effectiveness in reducing absolute acceleration responses. However, this effectiveness comes with a compromise on large isolation deformation, which may result in various issues, such as pounding and/or unseating damages of bridge decks. To address these issues, a negative stiffness enhanced tuned mass damper (NS-TMD) was proposed, aiming to minimize absolute acceleration while simultaneously limiting isolation deformation, and its control effectiveness has been demonstrated. However, the previous studies primarily focused on single-objective optimization without considering NS-TMD stroke, and the conventional negative stiffness (NS) devices, e.g., the pre-compressed helical springs with revolute joints, could not be well compatible with NS-TMD due to limited operating range. To this end, this study proposes a novel NS-TMD, which consists of a TMD with a curved-type mass block and an NS element based on a cam-roller-spring (CRS) mechanism. The working mechanism of the novel NS-TMD is first introduced, and its mechanical model is formulated. This novel system is then applied to a typical isolated bridge to illustrate its control effectiveness. Equilibrium equations and state space formulations of the system are derived. Subsequently, parametric analysis on NS-TMD is performed, followed by the proposal of a multi-objective optimization strategy to simultaneously minimize the relative displacement of the bridge deck and the stroke of NS-TMD. Finally, the control performance of NS-TMD is systematically evaluated. Numerical results show that the optimized NS-TMD not only reduces the deck displacement of the bridge system (with a maximum reduction ratio of 49.50 %) but also decreases its absolute acceleration. Furthermore, NS-TMD can achieve superior control performance in terms of the deck displacement, while limiting the stroke within a reasonable range. In summary, NS-TMD is a highly efficient alternative to conventional TMDs in terms of control effectiveness and feasibility. [Display omitted] •The novel NS-TMD integrates a curved-type mass block with a CRS-based NS element.•A performance-based multi-objective optimization strategy for NS-TMD is developed.•Optimized NS-TMD simultaneously reduces both deck displacement and acceleration.•NS-TMD achieves superior control performance while limiting stroke within reasonable ranges.•NS-TMD surpasses conventional TMDs in control effectiveness.
ArticleNumber 119416
Author Du, Xiuli
Ma, Ruisheng
Jiang, Shaodong
Bi, Kaiming
Song, Jian
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Keywords Control performance
Isolated bridge
Multi-objective optimization
Negative stiffness enhanced tuned mass damper
Earthquake ground motions
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  ident: 10.1016/j.engstruct.2024.119416_bib34
  article-title: KDamping: a stiffness based vibration absorption concept
  publication-title: J Vib Control
  doi: 10.1177/1077546316646514
– volume: 30
  start-page: 707
  year: 2008
  ident: 10.1016/j.engstruct.2024.119416_bib11
  article-title: Optimal tuned mass damper for seismic applications and practical design formulas
  publication-title: Eng Struct
  doi: 10.1016/j.engstruct.2007.05.007
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Snippet Seismic isolators have been extensively utilized in the field of structural vibration control due to their superior control effectiveness in reducing absolute...
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elsevier
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StartPage 119416
SubjectTerms Control performance
Earthquake ground motions
Isolated bridge
Multi-objective optimization
Negative stiffness enhanced tuned mass damper
Title Negative stiffness enhanced tuned mass damper (NS-TMD) for seismic induced response mitigation of isolated bridges
URI https://dx.doi.org/10.1016/j.engstruct.2024.119416
Volume 325
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