Effect of Soil-Structure Interaction on the Torsional Behavior of L-Shaped RC Buildings under Bi-Directional Ground Motions
Öz
This study investigates the seismic torsional response of a nine-story L-shaped reinforced concrete (RC) building, with particular emphasis on the effects of soil-structure interaction (SSI). Using three-dimensional nonlinear dynamic analyses in SAP2000, the building’s performance was evaluated under 30 pairs of scaled bidirectional ground motion records. SSI effects were modeled using the substructure method, with soil properties corresponding to ZC soil class as defined by the Turkish Seismic Code (TBEC-2018). Torsional behavior coefficients (ηbi) were computed from the displacement differentials obtained, and fragility curves were developed using ηbi as the engineering demand parameter. The results showed that SSI increased the fundamental periods by approximately 8% and torsional irregularity by up to 30% compared to fixed-base conditions. Fragility analysis indicated that the probability of exceeding the critical ηbi value of 1.2 was approximately 10% under fixed-base conditions and about 40% when SSI was considered. These findings highlight the significant impact of SSI on the torsional response of irregular structures and emphasize the importance of accounting for SSI effects in the seismic design and performance assessment of RC buildings.
Anahtar Kelimeler
Torsional irregularity Soil-structure interaction Nonlinear dynamic analysis Fragility curve L-shaped building
Etik Beyan
Ethics committee approval was not required for this study because of there was no study on animals or humans.
Destekleyen Kurum
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Teşekkür
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Kaynakça
- Abdel Raheem KA, Abdel Raheem SE, Soghair HM, Ahmed MH, 2010. Evaluation of seismic performance of multistory buildings designed according to Egyptian code. J Eng Sci Assiut Univ 38(2): 381-402.
- Abdel Raheem SE, Ahmed MM, Ahmed MM, Abdel-shafy AG. 2018. Evaluation of plan configuration irregularity effects on seismic response demands of L-shaped MRF buildings. Bull Earthq Eng 16: 3845-3869.
- Bharti AK, Garg V, Chandrawanshi S. 2025. A critical review of seismic soil-structure interaction analysis. J Istruc 72: 108221.
- Carvalho G, Bento R, Bhatt C. 2013. Nonlinear static and dynamic analyses of reinforced concrete buildings—Comparison of different modelling approaches. Earthq Struct 4(5): 451-470.
- Das PK, Dutta SC, Datta TK. 2021. Seismic behavior of plan and vertically irregular structures: state of art and future challenges. Nat Hazards Rev 22(2): 04020062.
- De Stefano M, Pintucchi B. 2008. A review of research on seismic behaviour of irregular building structures since 2002. Bull Earthq Eng 6: 285-308.
- Forcellini D. 2021. Analytical fragility curves of shallow-founded structures subjected to soil-structure interaction (SSI) effects. Soil Dyn Earthq Eng 141: 106487.
- Najar IA, Ahmadi R, Amuda AG, Mourad R, Bendary NE, Ismail I, Tang S. 2025. Advancing soil-structure interaction (SSI): a comprehensive review of current practices, challenges, and future directions. J Infrastruct Preserv Resil 6(1): 5.
- Newmark NM. 1959. A method of computation for structural dynamics. J Eng Mech Div 85(3): 67-94.
- NIST G. 2012. Soil-structure interaction for building structures. National Earthquake Hazards Reduction Program (NEHRP), pp: 1-20.
- Oz I. 2025. Seismic pounding effects of typical midrise reinforced concrete structures subjected to soil–structure interaction effects. J Steng 151(2): 05024005.
- Ozer E, Inel M. 2025. The effect of single and combined use of base isolator and fluid viscous damper on seismic performance in a conventional RC building with torsional irregularity. J Build Eng 101: 111898.
- PEER. Pacific Earthquake Engineering Research Center. Strong ground motion database (accessed date: November, 2024). https://ngawest2.berkeley.edu/
- Shirzadi M, Behnamfar F, Asadi P. 2020. Effects of soil–structure interaction on inelastic response of torsionally-coupled structures. Bull Earthq Eng 18: 1213-1243.
- Solomon AA, Hemalatha G. 2013. Limitation of irregular structure for seismic response. Int J Civil Struct Eng 3(3): 579-590.
- Sucuoğlu H, Kaatsız K. 2021. Torsional ductility spectrum for predicting ductility distribution in simple asymmetric‐plan structures. Earthq Eng Struct Dyn 50(2): 538-559.
- TBEC. 2018. Turkish Seismic Earthquake Code, pp: 1-416.
Effect of Soil-Structure Interaction on the Torsional Behavior of L-Shaped RC Buildings under Bi-Directional Ground Motions
Öz
This study investigates the seismic torsional response of a nine-story L-shaped reinforced concrete (RC) building, with particular emphasis on the effects of soil-structure interaction (SSI). Using three-dimensional nonlinear dynamic analyses in SAP2000, the building’s performance was evaluated under 30 pairs of scaled bidirectional ground motion records. SSI effects were modeled using the substructure method, with soil properties corresponding to ZC soil class as defined by the Turkish Seismic Code (TBEC-2018). Torsional behavior coefficients (ηbi) were computed from the displacement differentials obtained, and fragility curves were developed using ηbi as the engineering demand parameter. The results showed that SSI increased the fundamental periods by approximately 8% and torsional irregularity by up to 30% compared to fixed-base conditions. Fragility analysis indicated that the probability of exceeding the critical ηbi value of 1.2 was approximately 10% under fixed-base conditions and about 40% when SSI was considered. These findings highlight the significant impact of SSI on the torsional response of irregular structures and emphasize the importance of accounting for SSI effects in the seismic design and performance assessment of RC buildings.
Anahtar Kelimeler
Torsional irregularity Soil-structure interaction Nonlinear dynamic analysis Fragility curve L-shaped building
Etik Beyan
Ethics committee approval was not required for this study because of there was no study on animals or humans.
Kaynakça
- Abdel Raheem KA, Abdel Raheem SE, Soghair HM, Ahmed MH, 2010. Evaluation of seismic performance of multistory buildings designed according to Egyptian code. J Eng Sci Assiut Univ 38(2): 381-402.
- Abdel Raheem SE, Ahmed MM, Ahmed MM, Abdel-shafy AG. 2018. Evaluation of plan configuration irregularity effects on seismic response demands of L-shaped MRF buildings. Bull Earthq Eng 16: 3845-3869.
- Bharti AK, Garg V, Chandrawanshi S. 2025. A critical review of seismic soil-structure interaction analysis. J Istruc 72: 108221.
- Carvalho G, Bento R, Bhatt C. 2013. Nonlinear static and dynamic analyses of reinforced concrete buildings—Comparison of different modelling approaches. Earthq Struct 4(5): 451-470.
- Das PK, Dutta SC, Datta TK. 2021. Seismic behavior of plan and vertically irregular structures: state of art and future challenges. Nat Hazards Rev 22(2): 04020062.
- De Stefano M, Pintucchi B. 2008. A review of research on seismic behaviour of irregular building structures since 2002. Bull Earthq Eng 6: 285-308.
- Forcellini D. 2021. Analytical fragility curves of shallow-founded structures subjected to soil-structure interaction (SSI) effects. Soil Dyn Earthq Eng 141: 106487.
- Najar IA, Ahmadi R, Amuda AG, Mourad R, Bendary NE, Ismail I, Tang S. 2025. Advancing soil-structure interaction (SSI): a comprehensive review of current practices, challenges, and future directions. J Infrastruct Preserv Resil 6(1): 5.
- Newmark NM. 1959. A method of computation for structural dynamics. J Eng Mech Div 85(3): 67-94.
- NIST G. 2012. Soil-structure interaction for building structures. National Earthquake Hazards Reduction Program (NEHRP), pp: 1-20.
- Oz I. 2025. Seismic pounding effects of typical midrise reinforced concrete structures subjected to soil–structure interaction effects. J Steng 151(2): 05024005.
- Ozer E, Inel M. 2025. The effect of single and combined use of base isolator and fluid viscous damper on seismic performance in a conventional RC building with torsional irregularity. J Build Eng 101: 111898.
- PEER. Pacific Earthquake Engineering Research Center. Strong ground motion database (accessed date: November, 2024). https://ngawest2.berkeley.edu/
- Shirzadi M, Behnamfar F, Asadi P. 2020. Effects of soil–structure interaction on inelastic response of torsionally-coupled structures. Bull Earthq Eng 18: 1213-1243.
- Solomon AA, Hemalatha G. 2013. Limitation of irregular structure for seismic response. Int J Civil Struct Eng 3(3): 579-590.
- Sucuoğlu H, Kaatsız K. 2021. Torsional ductility spectrum for predicting ductility distribution in simple asymmetric‐plan structures. Earthq Eng Struct Dyn 50(2): 538-559.
- TBEC. 2018. Turkish Seismic Earthquake Code, pp: 1-416.
Ayrıntılar
| Birincil Dil | İngilizce |
|---|---|
| Konular | Betonarme Yapılar, Deprem Mühendisliği |
| Bölüm | Research Articles |
| Yazarlar | |
| Erken Görünüm Tarihi | 9 Temmuz 2025 |
| Yayımlanma Tarihi | 15 Eylül 2025 |
| Gönderilme Tarihi | 23 Mart 2025 |
| Kabul Tarihi | 11 Haziran 2025 |
| Yayımlandığı Sayı | Yıl 2025 Cilt: 8 Sayı: 5 |
Kaynak Göster
