Distribution of strong earthquake input energy in tall buildings equipped with damped outriggers

Morales‐Beltran, Mauricio; Turan, Gürsoy; Yıldırım, Umut; Paul, J.C.

doi:10.1002/tal.1463

Cited by 20 publications

(11 citation statements)

References 29 publications

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“…For instance, no change and a decrease from 0.23 to 0.14 under strong and severe motion, respectively, are the results of comparing the cases of the conventional and double damped configurations. This relatively small decrease in E H / E I may be explained by two observations: (a) As indicated by a previous study of the authors, the dampers' damping coefficient ( C d ) and the outrigger's location (λ) are the parameters that most influence the tall building's response. Because these two parameters have been already optimized in each of the studied configurations, further improvements, beyond each optimal, are unlikely to take place; (b) as suggested by columns E D / E I and E dampers / E I , most of the energy dissipated by the dampers seems to be partially subtracted from that dissipated from the inherent structural damping.…”

Section: Discussionmentioning

confidence: 72%

“…From previous studies, it is clear that under optimal design conditions, the addition of viscous dampers reduces both the OTM and overall stresses in the core, outriggers, and perimeter columns.…”

Section: Discussionmentioning

confidence: 99%

“…Properties of the steel are derived from Eurocode 3 . More details on the non‐linear settings of these FE models in Diana‐FEA can be found elsewhere …”

Section: Methodsmentioning

confidence: 99%

“…This article provides an analytical framework to comparatively assess the distribution of seismic energy in tall buildings equipped with viscous damped outriggers, that is, with outriggers that have one or more viscous damper installed between their ends and the perimeter columns. Because previous research developed by the authors showed that the energy dissipation capacity of a single set of outrigger will not prevent damage under strong earthquakes, a subsequent question was whether adding another set of outriggers would enhance such performance. In other words, if a single damped outrigger structure is designed to reach an optimal damping ratio, could this damping ratio still be increased by the addition of another set of outriggers?…”

Section: Introductionmentioning

confidence: 99%

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Energy dissipation and performance assessment of double damped outriggers in tall buildings under strong earthquakes

Morales‐Beltran

Turan

Dursun

et al. 2018

Structural Design Tall Build

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The use of a single set of outriggers equipped with oil viscous dampers increases the damping ratio of tall buildings in about 6-10%, depending on the loading conditions. However, could this ratio be further increased by the addition of another set of outriggers? Should this additional set include dampers too? To answer these questions, several double damped outrigger configurations for tall buildings are investigated and compared with an optimally designed single damped outrigger, located at elevation 0.7 of the total building's height (h). Using free vibration, double outrigger configurations increasing damping up to a ratio equal to the single-based optimal are identified. Next, selected configurations are subjected to several levels of eight ground motions to compare their capability for avoiding damage under critical excitations. Last, a simplified economic analysis highlights the advantages of each optimal configuration in terms of cost savings. The results show that, within the boundaries of this study, combining a damped outrigger at 0.5h with a conventional outrigger at 0.7h is more effective in reducing hysteretic energy ratios and economically viable if compared with a single damped outrigger solution. Moreover, double damped outrigger configurations for tall buildings exhibit broader display of optimal combinations, which offer flexibility of design to the high-rise architecture.

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Section: Discussionmentioning

confidence: 72%

Section: Discussionmentioning

confidence: 99%

“…Properties of the steel are derived from Eurocode 3 . More details on the non‐linear settings of these FE models in Diana‐FEA can be found elsewhere …”

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Energy dissipation and performance assessment of double damped outriggers in tall buildings under strong earthquakes

Morales‐Beltran

Turan

Dursun

et al. 2018

Structural Design Tall Build

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“…An opposing concentrated moment is generated in the core upon applying lateral loads as shown in Figures and . Recent research has been carried out on the seismic response of outrigger‐braced buildings (e.g., other studies).…”

Section: Introductionmentioning

confidence: 99%

Analysis of outrigger‐braced reinforced concrete supertall buildings: Core‐supported and tube‐in‐tube lateral systems

Kafina¹,

Sagaseta

2018

Structural Design Tall Build

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This study is primarily focused on the approximate analysis of reinforced concrete outriggers which are commonly used in the design and construction of supertall buildings subject to distributed horizontal loads. Existing global analysis formulae that provide preliminary results for lateral deflections and moments are reviewed for two lateral load resisting systems, namely, core-supported-with-outrigger (CSOR) system and less frequent tube-in-tube-with-outrigger (TTOR) system. These formulae are only applicable for CSOR and neglect the reverse rotation of the outrigger actually suffered due to the propping action from the outer columns and give rather high predictions of the deflections compared with advanced numerical finite element (FE) models. An improved model is proposed which overcomes this issue and provides more consistent results to FE predictions. The same can also be extended to TTOR.Several case studies are investigated to verify the accuracy of the proposed methodologies. The global analysis is followed by the local analysis of reinforced concrete outrigger beams using strut-and-tie modelling and non-linear FE analysis to obtain optimized reinforcement layouts (reduction of quantities of reinforcement). The results highlight the different challenges in detailing such structural members which are heavily loaded (high congestion of reinforcement), and the behaviour at failure can be brittle.

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Shaking table test of a damped‐outrigger system incorporating friction dampers

Lin

Chen

Chung

2023

Earthq Engng Struct Dyn

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The main purpose of this study is to investigate the seismic performance of a damped‐outrigger system incorporating friction dampers through numerical analysis and shaking table tests. A 9‐m‐tall steel structure specimen was designed by scaling down a 20‐story benchmark model. The specimen was equally divided into 10 floors; the outrigger beams together with the friction dampers could be installed in different floors. The normal force in the friction damper was adjustable so that its energy performance could be modified during the test. The seismic response of the specimen was evaluated by performing response spectral analysis (RSA) using the OpenSees numerical model. The equivalent damping ratio was included in the RSA to evaluate the energy dissipation resulting from the friction dampers. Based on the RSA results, the specimen configurations when outrigger was located at the sixth (6F), eighth (8F), and roof floors (RF) and when the normal force in the friction damper varied between 5, 10, and 20 kN were tested by imposing five different ground motions with the peak ground acceleration of 0.64g. Both the RSA and test results indicated that the maximum roof drift of the specimen was around 0.7, 0.4, and 0.3% rad., when the outrigger was located at the RF, 8F, and 6F, respectively. The greater normal force applied in the friction damper generally result in a greater amount of energy dissipation and a smaller roof drift response. Based on the experimental and numerical results, the optimal design of the damped‐outrigger system incorporating friction dampers are demonstrated in this study.

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Distribution of strong earthquake input energy in tall buildings equipped with damped outriggers

Cited by 20 publications

References 29 publications

Energy dissipation and performance assessment of double damped outriggers in tall buildings under strong earthquakes

Energy dissipation and performance assessment of double damped outriggers in tall buildings under strong earthquakes

Analysis of outrigger‐braced reinforced concrete supertall buildings: Core‐supported and tube‐in‐tube lateral systems

Shaking table test of a damped‐outrigger system incorporating friction dampers

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