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Enhancing the seismic performance of high-rise buildings with lead rubber bearing isolators

Year 2023, Volume: 7 Issue: 2, 99 - 107, 15.04.2023
https://doi.org/10.31127/tuje.1026994

Abstract

Recent earthquakes have enforced the engineering community to design seismically more efficient buildings through the energy dissipation systems. For this purpose, this paper investigates the seismic behavior of a high-rise building with a series of base isolation systems. Firstly, a 20-storey steel frame is selected as a fixed-base building, and then equipped with lead rubber bearings (LRBs). In the modelling of LRB, isolation period is alternatively varied as 4, 4.5, and 5 sec to evaluate the effectiveness of the isolator characteristic on the seismic performance of the high-rise base-isolated buildings. The seismic responses of the fixed-base and base-isolated buildings evaluated through a series of time-history analyses are performed using natural ground motion records. The analysis results are compared using engineering demand parameters such as storey displacement, isolator displacement, relative displacement, roof drift, interstorey drift ratio, absolute acceleration, base shear, base moment, input energy, and hysteretic curve. It is revealed that adjusting the isolation period in the design of LRB improved the seismic performance of the base-isolated high-rise steel buildings.

References

  • Murru, M., Akinci, A., Falcone, G., Pucci, S., Console, R., & Parsons, T. (2016). M≥ 7 earthquake rupture forecast and time‐dependent probability for the Sea of Marmara region, Turkey. Journal of Geophysical Research: Solid Earth, 121(4), 2679-2707.
  • TEC-2007, Turkish Earthquake Code, Ministry of Public Works and Settlement, Republic of Turkey, Ankara.
  • TBEC 2018 – Turkish Building Earthquake Code 2018, Republic of Turkey Ministry of Interior Disaster and Emergency Management Presidency, Ankara, Turkey.
  • Xu, Y., Becker, T. C., & Guo, T. (2021). Design optimization of triple friction pendulums for high-rise buildings considering both seismic and wind loads. Soil Dynamics and Earthquake Engineering, 142, 106568.
  • Markou, A. A., Stefanou, G., & Manolis, G. D. (2018). Stochastic response of structures with hybrid base isolation systems. Engineering Structures, 172, 629-643.
  • Skinner, R. I., Robinson, W. H., & McVerry, G. H. (1993). An introduction to seismic isolation. Wiley.
  • Park, K. S., Jung, H. J., & Lee, I. W. (2002). A comparative study on aseismic performances of base isolation systems for multi-span continuous bridge. Engineering Structures, 24(8), 1001-1013.
  • Kurino, S., Wei, W., & Igarashi, A. (2021). Seismic fragility and uncertainty mitigation of cable restrainer retrofit for isolated highway bridges incorporated with deteriorated elastomeric bearings. Engineering Structures, 237, 112190.
  • Zordan, T., Liu, T., Briseghella, B., & Zhang, Q. (2014). Improved equivalent viscous damping model for base-isolated structures with lead rubber bearings. Engineering Structures, 75, 340-352.
  • Ahmadipour, M., & Alam, M. S. (2017). Sensitivity analysis on mechanical characteristics of lead-core steel-reinforced elastomeric bearings under cyclic loading. Engineering Structures, 140, 39-50.
  • Pant, D. R., Constantinou, M. C., & Wijeyewickrema, A. C. (2013). Re-evaluation of equivalent lateral force procedure for prediction of displacement demand in seismically isolated structures. Engineering Structures, 52, 455-465.
  • Kazeminezhad, E., Kazemi, M. T., & Mirhosseini, S. M. (2020). Modified procedure of lead rubber isolator design used in the reinforced concrete building. Structures, 27, 2245-2273.
  • Deringöl, A. H., & Güneyisi, E. M. (2020). Effect of lead rubber bearing on seismic response of regular and irregular frames in elevation. Pamukkale Üniversitesi Mühendislik Bilimleri Dergisi, 26(6), 1076-1085.
  • Shakouri, A., Amiri, G. G., & Salehi, M. (2021). Effects of ductility and connection design on seismic responses of base-isolated steel moment-resisting frames. Soil Dynamics and Earthquake Engineering, 143, 106647.
  • Ye, K., Xiao, Y., & Hu, L. (2019). A direct displacement-based design procedure for base-isolated building structures with lead rubber bearings (LRBs). Engineering Structures, 197, 109402.
  • Gupta, P. K., Ghosh, G., & Pandey, D. K. (2021). Parametric study of effects of vertical ground motions on base isolated structures. Journal of Earthquake Engineering, 25(3), 434-454.
  • Habib, A., Houri, A. A., & Yildirim, U. (2021). Comparative study of base-isolated irregular RC structures subjected to pulse-like ground motions with low and high PGA/PGV ratios. Structures, 31, 1053-1071.
  • Altalabani, D., Hejazi, F., Rashid, R. S. B. M., & Abd Aziz, F. N. A. (2021). Development of new rectangular rubber isolators for a tunnel-form structure subjected to seismic excitations. Structures, 32, 1522-1542.
  • Zhang, R. J., & Li, A. Q. (2021). Experimental study on loading-rate dependent behavior of scaled high performance rubber bearings. Construction and Building Materials, 279, 122507.
  • Deringöl, A. H., & Güneyisi, E. M. (2021). Effect of Using High Damping Rubber Bearings for Seismic Isolation of the Buildings. International Journal of Steel Structures, 21(5), 1698-1722.
  • Karavasilis, T. L. (2016). Assessment of capacity design of columns in steel moment resisting frames with viscous dampers. Soil Dynamics and Earthquake Engineering, 88, 215-222.
  • CEN, C. E. D. N. (2004). Eurocode 8: Design of structures for earthquake resistance Part 1. General rules, seismic actions and rules for buildings (EN 1998–1), Brussels.
  • American Society of Civil Engineers, ASCE. (2010). Minimum design loads for buildings and other structures. ASCE/SEI 7-10, Reston, VA.
  • ASCE 7-05. (2005). Minimum Design Loads for Buildings and Other Structures. American Society of Civil Engineers, Reston, Virginia.
  • FEMA (Federal Emergency Management Agency) (2000). Prestandard and commentary for the seismic rehabilitation of building. FEMA-356, D.C.
  • Computers and Structures, Inc. SAP 2000 v20.0.0 (2017). Static and dynamic finite element analysis of structures, Berkeley, California.
  • Markou, A. A., & Manolis, G. D. (2016). Mechanical models for shear behavior in high damping rubber bearings. Soil Dynamics and Earthquake Engineering, 90, 221-226.
  • Park, Y. J., Wen, Y. K., & Ang, A. H. S. (1986). Random vibration of hysteretic systems under bi‐directional ground motions. Earthquake engineering & structural dynamics, 14(4), 543-557.
  • Wen, Y. K. (1976). Method for random vibration of hysteretic systems. Journal of the engineering mechanics division, 102(2), 249-263.
  • Naeim, F., & Kelly, J. M. (1999). Design of seismic isolated structures: from theory to practice. John Wiley & Sons.
  • PEER (2011). The Pacific Earthquake Engineering Research Center. User’s Manual for the PEER Ground Motion Database Application. Berkeley: University of California.
  • Chopra, A. K. (1995). Dynamics of Structures: Theory and Applications to Earthquake Engineering. Englewood Cliffs, N.J: Prentice Hall.
  • Guan, Y., Zhou, X., Yao, X., & Shi, Y. (2020). Seismic performance of prefabricated sheathed cold-formed thin-walled steel buildings: shake table test and numerical analyses. Journal of Constructional Steel Research, 167, 105837.
  • Avila, L., Vasconcelos, G., Lourenço, P. B. (2018). Experimental study on loading-rate dependent behavior of scaled high performance rubber bearings. Engineering Structures, 155, 298–314.
  • Gajan, S., & Saravanathiiban, D. S. (2011). Modeling of energy dissipation in structural devices and foundation soil during seismic loading. Soil Dynamics and Earthquake Engineering, 31(8), 1106-1122.
Year 2023, Volume: 7 Issue: 2, 99 - 107, 15.04.2023
https://doi.org/10.31127/tuje.1026994

Abstract

References

  • Murru, M., Akinci, A., Falcone, G., Pucci, S., Console, R., & Parsons, T. (2016). M≥ 7 earthquake rupture forecast and time‐dependent probability for the Sea of Marmara region, Turkey. Journal of Geophysical Research: Solid Earth, 121(4), 2679-2707.
  • TEC-2007, Turkish Earthquake Code, Ministry of Public Works and Settlement, Republic of Turkey, Ankara.
  • TBEC 2018 – Turkish Building Earthquake Code 2018, Republic of Turkey Ministry of Interior Disaster and Emergency Management Presidency, Ankara, Turkey.
  • Xu, Y., Becker, T. C., & Guo, T. (2021). Design optimization of triple friction pendulums for high-rise buildings considering both seismic and wind loads. Soil Dynamics and Earthquake Engineering, 142, 106568.
  • Markou, A. A., Stefanou, G., & Manolis, G. D. (2018). Stochastic response of structures with hybrid base isolation systems. Engineering Structures, 172, 629-643.
  • Skinner, R. I., Robinson, W. H., & McVerry, G. H. (1993). An introduction to seismic isolation. Wiley.
  • Park, K. S., Jung, H. J., & Lee, I. W. (2002). A comparative study on aseismic performances of base isolation systems for multi-span continuous bridge. Engineering Structures, 24(8), 1001-1013.
  • Kurino, S., Wei, W., & Igarashi, A. (2021). Seismic fragility and uncertainty mitigation of cable restrainer retrofit for isolated highway bridges incorporated with deteriorated elastomeric bearings. Engineering Structures, 237, 112190.
  • Zordan, T., Liu, T., Briseghella, B., & Zhang, Q. (2014). Improved equivalent viscous damping model for base-isolated structures with lead rubber bearings. Engineering Structures, 75, 340-352.
  • Ahmadipour, M., & Alam, M. S. (2017). Sensitivity analysis on mechanical characteristics of lead-core steel-reinforced elastomeric bearings under cyclic loading. Engineering Structures, 140, 39-50.
  • Pant, D. R., Constantinou, M. C., & Wijeyewickrema, A. C. (2013). Re-evaluation of equivalent lateral force procedure for prediction of displacement demand in seismically isolated structures. Engineering Structures, 52, 455-465.
  • Kazeminezhad, E., Kazemi, M. T., & Mirhosseini, S. M. (2020). Modified procedure of lead rubber isolator design used in the reinforced concrete building. Structures, 27, 2245-2273.
  • Deringöl, A. H., & Güneyisi, E. M. (2020). Effect of lead rubber bearing on seismic response of regular and irregular frames in elevation. Pamukkale Üniversitesi Mühendislik Bilimleri Dergisi, 26(6), 1076-1085.
  • Shakouri, A., Amiri, G. G., & Salehi, M. (2021). Effects of ductility and connection design on seismic responses of base-isolated steel moment-resisting frames. Soil Dynamics and Earthquake Engineering, 143, 106647.
  • Ye, K., Xiao, Y., & Hu, L. (2019). A direct displacement-based design procedure for base-isolated building structures with lead rubber bearings (LRBs). Engineering Structures, 197, 109402.
  • Gupta, P. K., Ghosh, G., & Pandey, D. K. (2021). Parametric study of effects of vertical ground motions on base isolated structures. Journal of Earthquake Engineering, 25(3), 434-454.
  • Habib, A., Houri, A. A., & Yildirim, U. (2021). Comparative study of base-isolated irregular RC structures subjected to pulse-like ground motions with low and high PGA/PGV ratios. Structures, 31, 1053-1071.
  • Altalabani, D., Hejazi, F., Rashid, R. S. B. M., & Abd Aziz, F. N. A. (2021). Development of new rectangular rubber isolators for a tunnel-form structure subjected to seismic excitations. Structures, 32, 1522-1542.
  • Zhang, R. J., & Li, A. Q. (2021). Experimental study on loading-rate dependent behavior of scaled high performance rubber bearings. Construction and Building Materials, 279, 122507.
  • Deringöl, A. H., & Güneyisi, E. M. (2021). Effect of Using High Damping Rubber Bearings for Seismic Isolation of the Buildings. International Journal of Steel Structures, 21(5), 1698-1722.
  • Karavasilis, T. L. (2016). Assessment of capacity design of columns in steel moment resisting frames with viscous dampers. Soil Dynamics and Earthquake Engineering, 88, 215-222.
  • CEN, C. E. D. N. (2004). Eurocode 8: Design of structures for earthquake resistance Part 1. General rules, seismic actions and rules for buildings (EN 1998–1), Brussels.
  • American Society of Civil Engineers, ASCE. (2010). Minimum design loads for buildings and other structures. ASCE/SEI 7-10, Reston, VA.
  • ASCE 7-05. (2005). Minimum Design Loads for Buildings and Other Structures. American Society of Civil Engineers, Reston, Virginia.
  • FEMA (Federal Emergency Management Agency) (2000). Prestandard and commentary for the seismic rehabilitation of building. FEMA-356, D.C.
  • Computers and Structures, Inc. SAP 2000 v20.0.0 (2017). Static and dynamic finite element analysis of structures, Berkeley, California.
  • Markou, A. A., & Manolis, G. D. (2016). Mechanical models for shear behavior in high damping rubber bearings. Soil Dynamics and Earthquake Engineering, 90, 221-226.
  • Park, Y. J., Wen, Y. K., & Ang, A. H. S. (1986). Random vibration of hysteretic systems under bi‐directional ground motions. Earthquake engineering & structural dynamics, 14(4), 543-557.
  • Wen, Y. K. (1976). Method for random vibration of hysteretic systems. Journal of the engineering mechanics division, 102(2), 249-263.
  • Naeim, F., & Kelly, J. M. (1999). Design of seismic isolated structures: from theory to practice. John Wiley & Sons.
  • PEER (2011). The Pacific Earthquake Engineering Research Center. User’s Manual for the PEER Ground Motion Database Application. Berkeley: University of California.
  • Chopra, A. K. (1995). Dynamics of Structures: Theory and Applications to Earthquake Engineering. Englewood Cliffs, N.J: Prentice Hall.
  • Guan, Y., Zhou, X., Yao, X., & Shi, Y. (2020). Seismic performance of prefabricated sheathed cold-formed thin-walled steel buildings: shake table test and numerical analyses. Journal of Constructional Steel Research, 167, 105837.
  • Avila, L., Vasconcelos, G., Lourenço, P. B. (2018). Experimental study on loading-rate dependent behavior of scaled high performance rubber bearings. Engineering Structures, 155, 298–314.
  • Gajan, S., & Saravanathiiban, D. S. (2011). Modeling of energy dissipation in structural devices and foundation soil during seismic loading. Soil Dynamics and Earthquake Engineering, 31(8), 1106-1122.
There are 35 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Ahmet Hilmi Deringöl 0000-0002-2665-8674

Esra Mete Güneyisi 0000-0002-4598-5582

Publication Date April 15, 2023
Published in Issue Year 2023 Volume: 7 Issue: 2

Cite

APA Deringöl, A. H., & Güneyisi, E. M. (2023). Enhancing the seismic performance of high-rise buildings with lead rubber bearing isolators. Turkish Journal of Engineering, 7(2), 99-107. https://doi.org/10.31127/tuje.1026994
AMA Deringöl AH, Güneyisi EM. Enhancing the seismic performance of high-rise buildings with lead rubber bearing isolators. TUJE. April 2023;7(2):99-107. doi:10.31127/tuje.1026994
Chicago Deringöl, Ahmet Hilmi, and Esra Mete Güneyisi. “Enhancing the Seismic Performance of High-Rise Buildings With Lead Rubber Bearing Isolators”. Turkish Journal of Engineering 7, no. 2 (April 2023): 99-107. https://doi.org/10.31127/tuje.1026994.
EndNote Deringöl AH, Güneyisi EM (April 1, 2023) Enhancing the seismic performance of high-rise buildings with lead rubber bearing isolators. Turkish Journal of Engineering 7 2 99–107.
IEEE A. H. Deringöl and E. M. Güneyisi, “Enhancing the seismic performance of high-rise buildings with lead rubber bearing isolators”, TUJE, vol. 7, no. 2, pp. 99–107, 2023, doi: 10.31127/tuje.1026994.
ISNAD Deringöl, Ahmet Hilmi - Güneyisi, Esra Mete. “Enhancing the Seismic Performance of High-Rise Buildings With Lead Rubber Bearing Isolators”. Turkish Journal of Engineering 7/2 (April 2023), 99-107. https://doi.org/10.31127/tuje.1026994.
JAMA Deringöl AH, Güneyisi EM. Enhancing the seismic performance of high-rise buildings with lead rubber bearing isolators. TUJE. 2023;7:99–107.
MLA Deringöl, Ahmet Hilmi and Esra Mete Güneyisi. “Enhancing the Seismic Performance of High-Rise Buildings With Lead Rubber Bearing Isolators”. Turkish Journal of Engineering, vol. 7, no. 2, 2023, pp. 99-107, doi:10.31127/tuje.1026994.
Vancouver Deringöl AH, Güneyisi EM. Enhancing the seismic performance of high-rise buildings with lead rubber bearing isolators. TUJE. 2023;7(2):99-107.
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