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AN innovative amplified viscously damped outrigger (AVDO) is newly proposed to improve the seismic damping effect of conventional viscousl damped outrigger (VDO) on super high-rise structures by mechanically increasing the displacement of the viscous damper (VD). To investigate the advantages of the damping effect on AVDO over VDO, the dynamic cyclic tests on VDO and AVDO were conducted to verify the feasibility of AVDO and superiority of AVDO over VDO. On this basis, six finite element models of a 258 m-high building with two types of damped outriggers placed at different heights were established and analyzed by dynamic time-history method. By comparing the seismic responses of numerical models, it is shown that upgrading VDO to AVDO can improve the damping efficiency of VDs and effectively expand the applicable damping placement in structural height, thus, the structure can achieve a better damping effect. An equivalent theoretical model of AVDO was established and validated by numerical analysis, which contributes to facilitating the modelling work and analysis of AVDO. However, experimental results showed that the outrigger deformation reduced the working displacement of VD seriously, indicating that the stiffness of the outrigger should be designed reasonably to withstand the damping force in motion. On this basis, the relationship between the working efficiency of VD and the stiffness ratio of outrigger to VD was derived and verified. To ensure the high work efficiency of the damper, the recommended stiffness limit of the outrigger supporting nonlinear VD was put forward, which fills a gap in the specification for practical applications.
Czasopismo
Rocznik
Tom
Strony
art. no. e37, 2023
Opis fizyczny
Bibliogr. 34 poz., rys., tab., wykr.
Twórcy
autor
- School of Civil Engineering, Xi’an University of Architecture and Technology, Xi’an 710055, People’s Republic of China
- Key Lab of Structural Engineering and Earthquake Resistance, Ministry of Education (XAUAT), Xi’an 710055, People’s Republic of China
autor
- School of Civil Engineering, Xi’an University of Architecture and Technology, Xi’an 710055, People’s Republic of China
autor
- School of Civil Engineering, Xi’an University of Architecture and Technology, Xi’an 710055, People’s Republic of China
autor
- School of Civil Engineering, Xi’an University of Architecture and Technology, Xi’an 710055, People’s Republic of China
- Key Lab of Structural Engineering and Earthquake Resistance, Ministry of Education (XAUAT), Xi’an 710055, People’s Republic of China
autor
- Key Lab of Structural Engineering and Earthquake Resistance, Ministry of Education (XAUAT), Xi’an 710055, People’s Republic of China
Bibliografia
- 1. Zhang XM, Ren QY, Liu WT, Yang SL, Zhou YL. Seismic design and elastic-plastic analysis of the hengda group super high-rise office buildings. Earthq Struct. 2020;19(3):175-88.
- 2. Aydin E, Farsangi EN, Ozturk B, Bogdanovic A, Dutkiewicz MR. Improvement of Building Resilience by Viscous Dampers: Springer; 2019.
- 3. Nie J-G, Ding R, Fan J-S, Tao M-X. Seismic Performance of Joints between Steel K-Style Outrigger Trusses and Concrete Cores in Tall Buildings. J Struct Eng. 2014;140(12):04014100.
- 4. He Z-H, Xu Z-D, Xue J-Y, Jing X-J, Dong Y-R, Li Q-Q. Theoretical and Experimental Research of Viscoelastic Damping Limb-Like-Structure Device with Coupling Nonlinear Characteristics. International Journal of Structural Stability and Dynamics. 2021;21(12).
- 5. Alberto Lago DT. Antony Wood. Damping Technologies for Tall Buildings: Butterworth-Heinemann; 2019.
- 6. Zhou Y, Zhang C, Lu X. Seismic performance of a damping outrigger system for tall buildings. Struct Control Health Monit. 2017;24(1): e1864.
- 7. Halperin I, Ribakov Y, Agranovich G. Optimal viscous dampers gains for structures subjected to earthquakes. Struct Control Health Monit. 2016;23(3):458-69.
- 8. Huang HC. Efficiency of the motion amplification device with viscous dampers and its application in high-rise buildings. Earthq Eng Eng Vib. 2010;8(4):521-36.
- 9. Lu Z, He X, Zhou Y. Performance-based seismic analysis on a super high-rise building with improved viscously damped outrigger system. Struct Control Health Monit. 2018;25(8): e2190.
- 10. He X, Lu Z. Seismic fragility assessment of a super tall building with hybrid control strategy using IDA method. Soil Dyn Earthq Eng. 2019;123:278-91.
- 11. Rob J, Smith MRW. The damped outrigger concept for tall buildings. Struct Design Tall Spec Build. 2007;16:501-17.
- 12. Smith R. The Damped Outrigger - Design and Implementation. International Journal of High-Rise Buildings. 2016;5(1):63-70.
- 13. Tan P, Fang C, Zhou F. Dynamic characteristics of a novel damped outrigger system. Earthq Eng Eng Vib. 2014;13(2):293-304.
- 14. Tan P, Fang CJ, Chang CM, Spencer BF, Zhou FL. Dynamic characteristics of novel energy dissipation systems with damped outriggers. Eng Struct. 2015;98:128-40.
- 15. Ikeda Y, Yamamoto M, Furuhashi T, Kurino H. Recent research and development of structural control in Japan. Japan Architectural Review. 2019;2(3):219-25.
- 16. Morales-Beltran M, Turan G, Yildirim U, Paul J. Distribution of strong earthquake input energy in tall buildings equipped with damped outriggers. Struct Design Tall Spec Build. 2018;27(8): e1463.
- 17. China Ministry of Construction (CMC). Code for design of building fire protection (GB 50016-2014). Beijing: China Architecture & Building Press; 2014. [in Chinese].
- 18. Ding J, Wang S, Wu H. Seismic performance analysis of viscous damping outrigger in super high-rise buildings. Struct Design Tall Spec Build. 2018;27(13): e1486.
- 19. Huang B, Takeuchi T. Dynamic Response Evaluation of Damped-Outrigger Systems with Various Heights. Earthq Spectra. 2017;33(2):665-85.
- 20. Baquero Mosquera JS, Almazan JL, Tapia NF. Amplification system for concentrated and distributed energy dissipation devices. Earthquake Eng Struct Dynam. 2016;45(6):935-56.
- 21. Zhu L, Guo P, Hua C, Shan S. Seismic Performance of an Efficient Scissor-Jack-Damper Configuration. Shock Vib. 2020;2020:1-11.
- 22. Polat E, Constantinou MC. Open-Space Damping System Description, Theory, and Verification. J Struct Eng. 2017;143(4):04016201.
- 23. Fang C, Spencer BF, Xu J, Tan P, Zhou F. Optimization of damped outrigger systems subject to stochastic excitation. Eng Struct. 2019;191:280-91.
- 24. China Ministry of Construction (CMC). Technical specification for seismic energy dissipation of buildings (JGJ 297-2013). Beijing, China: China Architecture & Building Press; 2013. [in Chinese].
- 25. Zhou J. Structural design and engineering practice of super high-rise buildings. Shanghai, China: Tongji University Press; 2017. ([in Chinese]).
- 26. China Ministry of Construction (CMC). Dampers for vibration energy dissipation of buildings (JG/T 209-2012). Beijing, China: China Architecture & Building Press; 2012. [in Chinese].
- 27. Japan Society of Seismic Isolation. Design and construction manual for passively controlled buildings. Tokyo, Japan: Japan Society of Seismic Isolation; 2007. ([in Japanese]).
- 28. PERFORM-3D v7: Computers and Structures, Inc.; 2018.
- 29. Components and Elements for Perform 3D. United States of America: Computers and Structures, Inc.; 2021.
- 30. Powell GH. Modeling for Structural Analysis : Behavior and Basics. Berkeley, California, USA: Computers and Structures, Inc.; 2010.
- 31. Rami Eid , Agha Hasan. Evaluation of Performance-Based Analysis and Design Methods for Asymmetrical Shear Wall Buildings. The 9th US National and 10th Canadian Conference on Earthquake Engineering2010.
- 32. Zhou Y, Zheng S, Chen L, Long L, Wang B. Experimental investigation into the seismic behavior of squat reinforced concrete walls subjected to acid rain erosion. Journal of Building Engineering. 2021;44.
- 33. China Ministry of Construction (CMC). Code for seismic design of buildings (GB 50011-2010). Beijing, China: China Architecture & Building Press; 2010. [in Chinese].
- 34. China Ministry of Construction (CMC).Technical specification for concrete structures of tall building (JGJ 3-2010). Beijing, China: China Architecture & Building Press; 2010. [in Chinese].
Uwagi
PL
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-d1cdefb1-2157-45d3-b024-d4ac01ab11ad