Design and Performance Parameters of Shear Walls: A Review

[1] Barda, F., Hanson, J.M., & Corley, W. (1977). Shear strength of low-rise walls with boundary elements. Special Publication, 53, 149–202. Barda F. Hanson J.M. Corley W. 1977 Shear strength of low-rise walls with boundary elements Special Publication 53 149 202 Search in Google Scholar

[2] Cardenas, A., Russell, H., & Corley, W. (1980). Strength of low-rise structural walls. Special Publication, 63, 221–242. Cardenas A. Russell H. Corley W. 1980 Strength of low-rise structural walls Special Publication 63 221 242 Search in Google Scholar

[3] Cardenas, A.E., & Magura, D.D. (1972). Strength of high-rise shear walls-rectangular cross section. Special Publication, 36, 119–150. Cardenas A.E. Magura D.D. 1972 Strength of high-rise shear walls-rectangular cross section Special Publication 36 119 150 Search in Google Scholar

[4] Oesterle, R., Aristizabal-Ochoa, J., Shiu, K. & Corley, W. (1984). Web crushing of reinforced concrete structural walls. Journal Proceedings, 81(3), 231–241. Oesterle R. Aristizabal-Ochoa J. Shiu K. Corley W. 1984 Web crushing of reinforced concrete structural walls Journal Proceedings 81 3 231 241 Search in Google Scholar

[5] Oesterle, R., Fiorato, A., Aristizabal-Ochoa, J., & Corley, W (1980). Hysteretic response of reinforced concrete structural walls. 63, 243–274. Oesterle R. Fiorato A. Aristizabal-Ochoa J. Corley W 1980 Hysteretic response of reinforced concrete structural walls 63 243 274 Search in Google Scholar

[6] Leafs, I.D., & Kotsovos, M.D. (1990). Behavior of reinforced concrete structural walls: strength, deformation characteristics, and failure mechanism. Structural Journal, 87(1), 23–31. Leafs I.D. Kotsovos M.D. 1990 Behavior of reinforced concrete structural walls: strength, deformation characteristics, and failure mechanism Structural Journal 87 1 23 31 Search in Google Scholar

[7] Lefas, I.D., & Kotsovos, M.D. (1990). Strength and deformation characteristics of reinforced concrete walls under load reversals. Structural Journal, 87(6), 716–726. Lefas I.D. Kotsovos M.D. 1990 Strength and deformation characteristics of reinforced concrete walls under load reversals Structural Journal 87 6 716 726 Search in Google Scholar

[8] Salonikios, T. N., Kappos, A. J., Tegos, I. A., & Penelis, G. G. (1999). Cyclic load behavior of low-slenderness reinforced concrete walls: Design basis and test results. Structural Journal, 96(4), 649–660. Salonikios T. N. Kappos A. J. Tegos I. A. Penelis G. G. 1999 Cyclic load behavior of low-slenderness reinforced concrete walls: Design basis and test results Structural Journal 96 4 649 660 Search in Google Scholar

[9] Taylor, C. P., Cote, P. A., & Wallace, J. W. (1998). Design of slender reinforced concrete walls with openings. Structural journal, 95(4), 420–433. Taylor C. P. Cote P. A. Wallace J. W. 1998 Design of slender reinforced concrete walls with openings Structural journal 95 4 420 433 Search in Google Scholar

[10] Mistri, A., Davis, R., & Sarkar, P. (2016). Condition assessment of fire affected reinforced concrete shear wall building – A case study. Advances in concrete construction, 4(2), 89. Mistri A. Davis R. Sarkar P. 2016 Condition assessment of fire affected reinforced concrete shear wall building – A case study Advances in concrete construction 4 2 89 10.12989/acc.2016.4.2.089 Search in Google Scholar

[11] Paulay, T., & Priestley, M. N. (1992). Seismic design of reinforced concrete and masonry buildings. Paulay T. Priestley M. N. 1992 Seismic design of reinforced concrete and masonry buildings 10.1002/9780470172841 Search in Google Scholar

[12] Ozturk, B. M. (2003). Seismic drift response of building structures in seismically active and near-fault regions. Doctoral dissertation, Purdue University. Ozturk B. M. 2003 Seismic drift response of building structures in seismically active and near-fault regions Doctoral dissertation Purdue University Search in Google Scholar

[13] Dazio, A., Beyer, K., & Bachmann, H. (2009). Quasistatic cyclic tests and plastic hinge analysis of RC structural walls. Engineering Structures, 31(7), 1556–1571. Dazio A. Beyer K. Bachmann H. 2009 Quasistatic cyclic tests and plastic hinge analysis of RC structural walls Engineering Structures 31 7 1556 1571 10.1016/j.engstruct.2009.02.018 Search in Google Scholar

[14] Aydin, A. C., & Bayrak, B. (2019). The torsional behavior of reinforced self-compacting concrete beams. Advances in Concrete Construction, 8(3), 187–198. Aydin A. C. Bayrak B. 2019 The torsional behavior of reinforced self-compacting concrete beams Advances in Concrete Construction 8 3 187 198 Search in Google Scholar

[15] Maali, M., Kılıç, M., Yaman, Z., Ağcakoca, E., & Aydın, A. C. (2019). Buckling and post-buckling behavior of various dented cylindrical shells using CFRP strips subjected to uniform external pressure: Comparison of theoretical and experimental data. Thin-Walled Structures, 137, 29–39. Maali M. Kılıç M. Yaman Z. Ağcakoca E. Aydın A. C. 2019 Buckling and post-buckling behavior of various dented cylindrical shells using CFRP strips subjected to uniform external pressure: Comparison of theoretical and experimental data Thin-Walled Structures 137 29 39 10.1016/j.tws.2018.12.042 Search in Google Scholar

[16] Baltacıoğlu, A. K., Baki, Ö., Civalek, Ö., & Akgöz, B. (2010). Is artificial neural network suitable for damage level determination of RC-Structures. International Journal of Engineering and Applied Sciences, 2(3), 71–81. Baltacıoğlu A. K. Baki Ö. Civalek Ö. Akgöz B. 2010 Is artificial neural network suitable for damage level determination of RC-Structures International Journal of Engineering and Applied Sciences 2 3 71 81 Search in Google Scholar

[17] Baltacıoğlu, A. K., Yavaş, A., Civalek, Ö., Öztürk, B., & Akgöz, B. (2010). Using of Fuzzy Logic Based Expert Systems for Fast Damage Determination of Structures After Earthquake. Journal of Balıkesir University Institute of Science, 12(1), 65–74. Baltacıoğlu A. K. Yavaş A. Civalek Ö. Öztürk B. Akgöz B. 2010 Using of Fuzzy Logic Based Expert Systems for Fast Damage Determination of Structures After Earthquake Journal of Balıkesir University Institute of Science 12 1 65 74 Search in Google Scholar

[18] Farvashany, F. E., Foster, S. J., & Rangan, B. V. (2008). Strength and deformation of high-strength concrete shearwalls. ACI structural journal, 105(1), 21. Farvashany F. E. Foster S. J. Rangan B. V. 2008 Strength and deformation of high-strength concrete shearwalls ACI structural journal 105 1 21 Search in Google Scholar

[19] Derecho, A. T., Iqbal, M., Fintel, M., & Corley, W. G. (1980). Loading history for use in quasi-static simulated earthquake loading tests. Special Publication, 63, 329–356. Derecho A. T. Iqbal M. Fintel M. Corley W. G. 1980 Loading history for use in quasi-static simulated earthquake loading tests Special Publication 63 329 356 Search in Google Scholar

[20] Calvi, G. M., Kingsley, G. R., & Magenes, G. (1996). Testing of masonry structures for seismic assessment. Earthquake spectra, 12(1), 145–162. Calvi G. M. Kingsley G. R. Magenes G. 1996 Testing of masonry structures for seismic assessment Earthquake spectra 12 1 145 162 10.1193/1.1585872 Search in Google Scholar

[21] Ozturk, B. (2008). Investigation of seismic behavior of reinforced concrete shearwall building frames subjected to ground motions from the 1999 turkish earthquakes. In 14^th World Conference on Earthquake Engineering. Ozturk B. 2008 Investigation of seismic behavior of reinforced concrete shearwall building frames subjected to ground motions from the 1999 turkish earthquakes In 14^th World Conference on Earthquake Engineering Search in Google Scholar

[22] Carrillo, J., & Alcocer, S. M. (2013). Experimental investigation on dynamic and quasi static behavior of low rise reinforced concrete walls. Earthquake Engineering & Structural Dynamics, 42(5), 635–652. Carrillo J. Alcocer S. M. 2013 Experimental investigation on dynamic and quasi static behavior of low rise reinforced concrete walls Earthquake Engineering & Structural Dynamics 42 5 635 652 10.1002/eqe.2234 Search in Google Scholar

[23] Bertero, V. V., Popov, E. P., Wang, T. Y., & Vallenas, J. (1977, January). Seismic design implications of hysteretic behavior of reinforced concrete structural walls. 6^th World Conference on Earthquake Engineering, 1898–1904. Bertero V. V. Popov E. P. Wang T. Y. Vallenas J. 1977 January) Seismic design implications of hysteretic behavior of reinforced concrete structural walls 6^th World Conference on Earthquake Engineering, 1898–1904 Search in Google Scholar

[24] Aktan, A. E., & Bertero, V. V. (1984). Seismic response of R/C frame-wall structures. Journal of Structural Engineering, 110(8), 1803–1821. Aktan A. E. Bertero V. V. 1984 Seismic response of R/C frame-wall structures Journal of Structural Engineering 110 8 1803 1821 10.1061/(ASCE)0733-9445(1984)110:8(1803) Search in Google Scholar

[25] Paulay, T., & Santhakumar, A. R. (1976). Ductile behavior of coupled shear walls. Journal of the Structural Division, 102(1), 93–108. Paulay T. Santhakumar A. R. 1976 Ductile behavior of coupled shear walls Journal of the Structural Division 102 1 93 108 10.1061/JSDEAG.0004279 Search in Google Scholar

[26] Tiecheng, W., Tianyu, L., & Hailong, Z. (2017). Tensile-shear mechanical performance test of reinforced concrete shear wall. Building Structure, 47(2), 64–69. Tiecheng W. Tianyu L. Hailong Z. 2017 Tensile-shear mechanical performance test of reinforced concrete shear wall Building Structure 47 2 64 69 Search in Google Scholar

[27] Ji, X., Cheng, X., & Xu, M. (2018). Coupled axial tension-shear behavior of reinforced concrete walls. Engineering Structures, 167, 132–142. Ji X. Cheng X. Xu M. 2018 Coupled axial tension-shear behavior of reinforced concrete walls Engineering Structures 167 132 142 10.1016/j.engstruct.2018.04.015 Search in Google Scholar

[28] Bakis, C. E., Bank, L. C., Brown, V., Cosenza, E., Davalos, J. F., Lesko, J. J., ... & Triantafillou, T. C. (2002). Fiber-reinforced polymer composites for construction – State-of-the-art review. Journal of composites for construction, 6(2), 73–87. Bakis C. E. Bank L. C. Brown V. Cosenza E. Davalos J. F. Lesko J. J. Triantafillou T. C. 2002 Fiber-reinforced polymer composites for construction – State-of-the-art review Journal of composites for construction 6 2 73 87 10.1061/(ASCE)1090-0268(2002)6:2(73) Search in Google Scholar

[29] Vecchio, F. J., de la Pena, O. A. H., Bucci, F., & Palermo, D. (2002). Behavior of repaired cyclically loaded shearwalls. ACI Structural Journal, 99(3), 327–334. Vecchio F. J. de la Pena O. A. H. Bucci F. Palermo D. 2002 Behavior of repaired cyclically loaded shearwalls ACI Structural Journal 99 3 327 334 Search in Google Scholar

[30] Mosallam, A. S., Bayraktar, A., Elmikawi, M., Pul, S., & Adanur, S. (2015). Polymer composites in construction: an overview, SOJ Materials Science & Engineering. Mosallam A. S. Bayraktar A. Elmikawi M. Pul S. Adanur S. 2015 Polymer composites in construction: an overview SOJ Materials Science & Engineering Search in Google Scholar

[31] Christidis, K. I., & Trezos, K. G. (2017). Experimental investigation of existing non-conforming RC shear walls. Engineering Structures, 140, 26–38. Christidis K. I. Trezos K. G. 2017 Experimental investigation of existing non-conforming RC shear walls Engineering Structures 140 26 38 10.1016/j.engstruct.2017.02.063 Search in Google Scholar

[32] Antoniades, K. K., Salonikios, T. N., & Kappos, A. J. (2005). Tests on seismically damaged reinforced concrete walls repaired and strengthened using fiber-reinforced polymers. Journal of Composites for Construction, 9(3), 236–246. Antoniades K. K. Salonikios T. N. Kappos A. J. 2005 Tests on seismically damaged reinforced concrete walls repaired and strengthened using fiber-reinforced polymers Journal of Composites for Construction 9 3 236 246 10.1061/(ASCE)1090-0268(2005)9:3(236) Search in Google Scholar

[33] Aydin, A. C., Yaman, Z., Ağcakoca, E., Kiliç, M., Maali, M., & Dizaji, A. A. (2020). CFRP effect on the buckling behavior of dented cylindrical shells. International Journal of Steel Structures, 20(2), 425–435. Aydin A. C. Yaman Z. Ağcakoca E. Kiliç M. Maali M. Dizaji A. A. 2020 CFRP effect on the buckling behavior of dented cylindrical shells International Journal of Steel Structures 20 2 425 435 10.1007/s13296-019-00294-4 Search in Google Scholar

[34] El-Sokkary, H., Galal, K., Ghorbanirenani, I., Léger, P., & Tremblay, R. (2013). Shake table tests on FRP-rehabilitated RC shear walls. Journal of Composites for Construction, 17(1), 79–90. El-Sokkary H. Galal K. Ghorbanirenani I. Léger P. Tremblay R. 2013 Shake table tests on FRP-rehabilitated RC shear walls Journal of Composites for Construction 17 1 79 90 10.1061/(ASCE)CC.1943-5614.0000312 Search in Google Scholar

[35] Layssi, H., Cook, W. D., & Mitchell, D. (2012). Seismic response and CFRP retrofit of poorly detailed shear walls. Journal of Composites for Construction, 16(3), 332–339. Layssi H. Cook W. D. Mitchell D. 2012 Seismic response and CFRP retrofit of poorly detailed shear walls Journal of Composites for Construction 16 3 332 339 10.1061/(ASCE)CC.1943-5614.0000259 Search in Google Scholar

[36] Paterson, J., & Mitchell, D. (2003). Seismic retrofit of shear walls with headed bars and carbon fiber wrap. Journal of Structural Engineering, 129(5), 606–614. Paterson J. Mitchell D. 2003 Seismic retrofit of shear walls with headed bars and carbon fiber wrap Journal of Structural Engineering 129 5 606 614 10.1061/(ASCE)0733-9445(2003)129:5(606) Search in Google Scholar

[37] Qazi, S., Michel, L., & Ferrier, E. (2019). Seismic behaviour of RC short shear wall strengthened with externally bonded CFRP strips. Composite Structures, 211, 390–400. Qazi S. Michel L. Ferrier E. 2019 Seismic behaviour of RC short shear wall strengthened with externally bonded CFRP strips Composite Structures 211 390 400 10.1016/j.compstruct.2018.12.038 Search in Google Scholar

[38] Carrillo, J., Lizarazo, J. M., & Bonett, R. (2015). Effect of lightweight and low-strength concrete on seismic performance of thin lightly-reinforced shear walls. Engineering Structures, 93, 61–69. Carrillo J. Lizarazo J. M. Bonett R. 2015 Effect of lightweight and low-strength concrete on seismic performance of thin lightly-reinforced shear walls Engineering Structures 93 61 69 10.1016/j.engstruct.2015.03.022 Search in Google Scholar

[39] Su, R.K.L., & Wong, S. M. (2007). Seismic behaviour of slender reinforced concrete shear walls under high axial load ratio. Engineering Structures, 29(8), 1957–1965. Su R.K.L. Wong S. M. 2007 Seismic behaviour of slender reinforced concrete shear walls under high axial load ratio Engineering Structures 29 8 1957 1965 10.1016/j.engstruct.2006.10.020 Search in Google Scholar

[40] Dong, Y. R., Xu, Z. D., Zeng, K., Cheng, Y., & Xu, C. (2018). Seismic behavior and cross-scale refinement model of damage evolution for RC shear walls. Engineering Structures, 167, 13–25. Dong Y. R. Xu Z. D. Zeng K. Cheng Y. Xu C. 2018 Seismic behavior and cross-scale refinement model of damage evolution for RC shear walls Engineering Structures 167 13 25 10.1016/j.engstruct.2018.03.096 Search in Google Scholar

[41] Zhang, Y., & Wang, Z. (2000). Seismic behavior of reinforced concrete shear walls subjected to high axial loading. Structural Journal, 97(5), 739–750. Zhang Y. Wang Z. 2000 Seismic behavior of reinforced concrete shear walls subjected to high axial loading Structural Journal 97 5 739 750 Search in Google Scholar

[42] Iliya, R., & Bertero, V. V. (1980). Effects of amount and arrangement of wall-panel reinforcement on hysteretic behavior of reinforced concrete walls. University of California, Earthquake Engineering Research Center. Iliya R. Bertero V. V. 1980 Effects of amount and arrangement of wall-panel reinforcement on hysteretic behavior of reinforced concrete walls University of California, Earthquake Engineering Research Center Search in Google Scholar

[43] Salonikios, T. N. (2002). Shear strength and deformation patterns of R/C walls with aspect ratio 1.0 and 1.5 designed to Eurocode 8 (EC8). Engineering Structures, 24(1), 39–49. Salonikios T. N. 2002 Shear strength and deformation patterns of R/C walls with aspect ratio 1.0 and 1.5 designed to Eurocode 8 (EC8) Engineering Structures 24 1 39 49 10.1016/S0141-0296(01)00076-1 Search in Google Scholar

[44] Tolou Kian, M. J., & Cruz-Noguez, C. (2018). Reinforced concrete shear walls detailed with innovative materials: seismic performance. Journal of Composites for Construction, 22(6), 04018052. Tolou Kian M. J. Cruz-Noguez C. 2018 Reinforced concrete shear walls detailed with innovative materials: seismic performance Journal of Composites for Construction 22 6 04018052 10.1061/(ASCE)CC.1943-5614.0000893 Search in Google Scholar

[45] Mohamed, N., Farghaly, A. S., Benmokrane, B., & Neale, K. W. (2014). Experimental investigation of concrete shear walls reinforced with glass fiber–reinforced bars under lateral cyclic loading. Journal of Composites for Construction, 18(3), A4014001. Mohamed N. Farghaly A. S. Benmokrane B. Neale K. W. 2014 Experimental investigation of concrete shear walls reinforced with glass fiber–reinforced bars under lateral cyclic loading Journal of Composites for Construction 18 3 A4014001 10.1061/(ASCE)CC.1943-5614.0000393 Search in Google Scholar

[46] Mattock, A. H. (1967). Discussion of “Rotational capacity of reinforced concrete beams”. Journal of the Structural Division, 93(2), 519–522. Mattock A. H. 1967 Discussion of “Rotational capacity of reinforced concrete beams” Journal of the Structural Division 93 2 519 522 10.1061/JSDEAG.0001678 Search in Google Scholar

[47] Priestley, M. N., Seible, F., & Calvi, G. M. (1996). Seismic design and retrofit of bridges. John Wiley & Sons. Priestley M. N. Seible F. Calvi G. M. 1996 Seismic design and retrofit of bridges John Wiley & Sons 10.1002/9780470172858 Search in Google Scholar

[48] Bohl, A., & Adebar, P. (2011). Plastic hinge lengths in high-rise concrete shear walls. ACI Structural Journal, 108(2), 148. Bohl A. Adebar P. 2011 Plastic hinge lengths in high-rise concrete shear walls ACI Structural Journal 108 2 148 Search in Google Scholar

[49] Park, W. S., & Yun, H. D. (2006). Seismic behaviour and design of steel coupling beams in a hybrid coupled shear wall systems. Nuclear Engineering and Design, 236(23), 2474–2484. Park W. S. Yun H. D. 2006 Seismic behaviour and design of steel coupling beams in a hybrid coupled shear wall systems Nuclear Engineering and Design 236 23 2474 2484 10.1016/j.nucengdes.2006.03.008 Search in Google Scholar

[50] Park, W. S., & Yun, H. D. (2005). Seismic behaviour of steel coupling beams linking reinforced concrete shear walls. Engineering structures, 27(7), 1024–1039. Park W. S. Yun H. D. 2005 Seismic behaviour of steel coupling beams linking reinforced concrete shear walls Engineering structures 27 7 1024 1039 10.1016/j.engstruct.2005.02.013 Search in Google Scholar

[51] Zhao, J., Cai, G., Larbi, A. S., Zhang, Y., Dun, H., Degée, H., & Vandoren, B. (2018). Hysteretic behaviour of steel fibre RC coupled shear walls under cyclic loads: Experimental study and modelling. Engineering Structures, 156, 92–104. Zhao J. Cai G. Larbi A. S. Zhang Y. Dun H. Degée H. Vandoren B. 2018 Hysteretic behaviour of steel fibre RC coupled shear walls under cyclic loads: Experimental study and modelling Engineering Structures 156 92 104 10.1016/j.engstruct.2017.11.006 Search in Google Scholar

[52] Aksogan, O., Arslan, H. M., & Choo, B. S. (2003). Forced vibration analysis of stiffened coupled shear walls using continuous connection method. Engineering structures, 25(4), 499–506. Aksogan O. Arslan H. M. Choo B. S. 2003 Forced vibration analysis of stiffened coupled shear walls using continuous connection method Engineering structures 25 4 499 506 10.1016/S0141-0296(02)00192-X Search in Google Scholar

[53] Chaallal, O., & Ghlamallah, N. (1996). Seismic response of flexibly supported coupled shear walls. Journal of Structural Engineering, 122(10), 1187–1197. Chaallal O. Ghlamallah N. 1996 Seismic response of flexibly supported coupled shear walls Journal of Structural Engineering 122 10 1187 1197 10.1061/(ASCE)0733-9445(1996)122:10(1187) Search in Google Scholar

[54] Chaailal, O., Thibodeau, S., Lescelleur, J., & Maleenfant, P. (1996). Steel Fiber or conventional reinforcement for concrete shearwalls. Concrete International, 18(6), 39–42. Chaailal O. Thibodeau S. Lescelleur J. Maleenfant P. 1996 Steel Fiber or conventional reinforcement for concrete shearwalls Concrete International 18 6 39 42 Search in Google Scholar

[55] Cheng, M. Y., Fikri, R., & Chen, C. C. (2015). Experimental study of reinforced concrete and hybrid coupled shear wall systems. Engineering Structures, 82, 214–225. Cheng M. Y. Fikri R. Chen C. C. 2015 Experimental study of reinforced concrete and hybrid coupled shear wall systems Engineering Structures 82 214 225 10.1016/j.engstruct.2014.10.039 Search in Google Scholar

[56] Zhao, J., Cai, G., Larbi, A. S., Zhang, Y., Dun, H., Degée, H., & Vandoren, B. (2018). Hysteretic behaviour of steel fibre RC coupled shear walls under cyclic loads: Experimental study and modelling. Engineering Structures, 156, 92–104. Zhao J. Cai G. Larbi A. S. Zhang Y. Dun H. Degée H. Vandoren B. 2018 Hysteretic behaviour of steel fibre RC coupled shear walls under cyclic loads: Experimental study and modelling Engineering Structures 156 92 104 10.1016/j.engstruct.2017.11.006 Search in Google Scholar

[57] Galano, L., & Vignoli, A. (2000). Seismic behavior of short coupling beams with different reinforcement layouts. Structural Journal, 97(6), 876–885. Galano L. Vignoli A. 2000 Seismic behavior of short coupling beams with different reinforcement layouts Structural Journal 97 6 876 885 Search in Google Scholar

[58] Zhang, J., Zheng, W., Yu, C., & Cao, W. (2018). Shaking table test of reinforced concrete coupled shear walls with single layer of web reinforcement and inclined steel bars. Advances in Structural Engineering, 21(15), 2282–2298. Zhang J. Zheng W. Yu C. Cao W. 2018 Shaking table test of reinforced concrete coupled shear walls with single layer of web reinforcement and inclined steel bars Advances in Structural Engineering 21 15 2282 2298 10.1177/1369433218772350 Search in Google Scholar

[59] Wang, T., Shang, Q., Wang, X., Li, J., & Kong, Z. A. (2018). Experimental validation of RC shear wall structures with hybrid coupling beams. Soil Dynamics and Earthquake Engineering, 111, 14–30. Wang T. Shang Q. Wang X. Li J. Kong Z. A. 2018 Experimental validation of RC shear wall structures with hybrid coupling beams Soil Dynamics and Earthquake Engineering 111 14 30 10.1016/j.soildyn.2018.04.021 Search in Google Scholar

[60] Ji, X., Wang, Y., Ma, Q., & Okazaki, T. (2017). Cyclic behavior of replaceable steel coupling beams. Journal of Structural Engineering, 143(2), 04016169. Ji X. Wang Y. Ma Q. Okazaki T. 2017 Cyclic behavior of replaceable steel coupling beams Journal of Structural Engineering 143 2 04016169 10.2749/222137815815775934 Search in Google Scholar

[61] Adams, P. F., Zimmerman, T. J. E., & MacGregor, J. G. (1987). Design and Behavior of Composite Ice-Resisting Walls. Port and Ocean Engineering Under Arctic Conditions., 1, 663–674. Adams P. F. Zimmerman T. J. E. MacGregor J. G. 1987 Design and Behavior of Composite Ice-Resisting Walls Port and Ocean Engineering Under Arctic Conditions. 1 663 674 Search in Google Scholar

[62] Matsuishi, M., & Iwata, S. (1987). Strength of Composite System Ice-Resisting Structures Steel/Concrete Composite Structural Systems, C-FER Publication No. 1. In Proceedings of a special symposium held in conjunction with POAC (Vol. 87). Matsuishi M. Iwata S. 1987 Strength of Composite System Ice-Resisting Structures Steel/Concrete Composite Structural Systems, C-FER Publication No. 1 In Proceedings of a special symposium held in conjunction with POAC (Vol. 87) Search in Google Scholar

[63] Oiino, F. (1987). Experimental Studies on Composite Members for Arctic Offshore Structures. POAC’87, 89–102. Oiino F. 1987 Experimental Studies on Composite Members for Arctic Offshore Structures POAC’87 89 102 Search in Google Scholar

[64] Li, X., & Li, X. (2017). Steel plates and concrete filled composite shear walls related nuclear structural engineering: Experimental study for out-of-plane cyclic loading. Nuclear Engineering and Design, 315, 144–154. Li X. Li X. 2017 Steel plates and concrete filled composite shear walls related nuclear structural engineering: Experimental study for out-of-plane cyclic loading Nuclear Engineering and Design 315 144 154 10.1016/j.nucengdes.2017.02.019 Search in Google Scholar

[65] Lu, X. L., Gan, C., & Wang, W. (2009). Study on seismic behavior of steel plate reinforced concrete shear walls. Journal of Building Structures, 30(5), 89–96. Lu X. L. Gan C. Wang W. 2009 Study on seismic behavior of steel plate reinforced concrete shear walls Journal of Building Structures 30 5 89 96 Search in Google Scholar

[66] Chunyu, C.T.X.C.T., & Peifu, X. (2011). Experimental study of the compression-bending behavior of composite shear walls of high axial compression ratios [J]. China Civil Engineering Journal, 6. Chunyu C.T.X.C.T. Peifu X. 2011 Experimental study of the compression-bending behavior of composite shear walls of high axial compression ratios [J] China Civil Engineering Journal 6 Search in Google Scholar

[67] Nie, J. G., Hu, H. S., Fan, J. S., Tao, M. X., Li, S. Y., & Liu, F. J. (2013). Experimental study on seismic behavior of high-strength concrete filled double-steel-plate composite walls. Journal of Constructional Steel Research, 88, 206–219. Nie J. G. Hu H. S. Fan J. S. Tao M. X. Li S. Y. Liu F. J. 2013 Experimental study on seismic behavior of high-strength concrete filled double-steel-plate composite walls Journal of Constructional Steel Research 88 206 219 10.1016/j.jcsr.2013.05.001 Search in Google Scholar

[68] Dan, D., Fabian, A., & Stoian, V. (2011). Theoretical and experimental study on composite steel–concrete shear walls with vertical steel encased profiles. Journal of constructional steel research, 67(5), 800–813. Dan D. Fabian A. Stoian V. 2011 Theoretical and experimental study on composite steel–concrete shear walls with vertical steel encased profiles Journal of constructional steel research 67 5 800 813 10.1016/j.jcsr.2010.12.013 Search in Google Scholar

[69] Meghdadaian, M., & Ghalehnovi, M. (2019). Improving seismic performance of composite steel plate shear walls containing openings. Journal of Building Engineering, 21, 336–342. Meghdadaian M. Ghalehnovi M. 2019 Improving seismic performance of composite steel plate shear walls containing openings Journal of Building Engineering 21 336 342 10.1016/j.jobe.2018.11.001 Search in Google Scholar

[70] Park, W. S., & Yun, H. D. (2006). Seismic behaviour and design of steel coupling beams in a hybrid coupled shear wall systems. Nuclear Engineering and Design, 236(23), 2474–2484. Park W. S. Yun H. D. 2006 Seismic behaviour and design of steel coupling beams in a hybrid coupled shear wall systems Nuclear Engineering and Design 236 23 2474 2484 10.1016/j.nucengdes.2006.03.008 Search in Google Scholar

[71] Lan, W., Ma, J., & Li, B. (2015). Seismic performance of steel–concrete composite structural walls with internal bracings. Journal of Constructional Steel Research, 110, 76–89. Lan W. Ma J. Li B. 2015 Seismic performance of steel–concrete composite structural walls with internal bracings Journal of Constructional Steel Research 110 76 89 10.1016/j.jcsr.2015.02.015 Search in Google Scholar

[72] Mao, C., Dong, J., Li, H., & Ou, J. (2012, April). Seismic performance of RC shear wall structure with novel shape memory alloy dampers in coupling beams. In Sensors and Smart Structures Technologies for Civil, Mechanical, and Aerospace Systems 2012 (Vol. 8345, p. 83454G). International Society for Optics and Photonics. Mao C. Dong J. Li H. Ou J. 2012 April Seismic performance of RC shear wall structure with novel shape memory alloy dampers in coupling beams In Sensors and Smart Structures Technologies for Civil, Mechanical, and Aerospace Systems 2012 (Vol. 8345, p. 83454G) International Society for Optics and Photonics 10.1117/12.917304 Search in Google Scholar

[73] Ji, X., Leong, T., Qian, J., Qi, W., & Yang, W. (2016). Cyclic shear behavior of composite walls with encased steel braces. Engineering Structures, 127, 117–128. Ji X. Leong T. Qian J. Qi W. Yang W. 2016 Cyclic shear behavior of composite walls with encased steel braces Engineering Structures 127 117 128 10.1016/j.engstruct.2016.08.041 Search in Google Scholar

[74] Astaneh-Asl, A. (2002). Seismic behavior and design of composite steel plate shear walls. Moraga, CA: Structural Steel Educational Council. Astaneh-Asl A. 2002 Seismic behavior and design of composite steel plate shear walls Moraga, CA Structural Steel Educational Council Search in Google Scholar

[75] Yeh, R. L., Tseng, C. C., & Hwang, S. J. (2018). Shear Strength of Reinforced Concrete Vertical Wall Segments under Seismic Loading. ACI Structural Journal. Yeh R. L. Tseng C. C. Hwang S. J. 2018 Shear Strength of Reinforced Concrete Vertical Wall Segments under Seismic Loading ACI Structural Journal 10.14359/51702377 Search in Google Scholar

[76] Wang, J., Sakashita, M., Kono, S., & Tanaka, H. (2012). Shear behaviour of reinforced concrete structural walls with eccentric openings under cyclic loading: experimental study. The Structural Design of Tall and Special Buildings, 21(9), 669–681. Wang J. Sakashita M. Kono S. Tanaka H. 2012 Shear behaviour of reinforced concrete structural walls with eccentric openings under cyclic loading: experimental study The Structural Design of Tall and Special Buildings 21 9 669 681 10.1002/tal.639 Search in Google Scholar

[77] Massone, L. M., Muñoz, G., & Rojas, F. (2019). Experimental and numerical cyclic response of RC walls with openings. Engineering Structures, 178, 318–330. Massone L. M. Muñoz G. Rojas F. 2019 Experimental and numerical cyclic response of RC walls with openings Engineering Structures 178 318 330 10.1016/j.engstruct.2018.10.038 Search in Google Scholar

[78] Qian, K., Li, B., & Liu, Y. (2017). Experimental and analytical study on load paths of RC squat walls with openings. Magazine of Concrete Research, 69(1), 1–23. Qian K. Li B. Liu Y. 2017 Experimental and analytical study on load paths of RC squat walls with openings Magazine of Concrete Research 69 1 1 23 10.1680/jmacr.15.00300 Search in Google Scholar

[79] Mohammadi Vojdan, B., & Aghayari, R. (2017). Investigating the seismic behavior of RC shear walls with openings strengthened with FRP sheets using different schemes. Scientia Iranica, 24(4), 1855–1865. Mohammadi Vojdan B. Aghayari R. 2017 Investigating the seismic behavior of RC shear walls with openings strengthened with FRP sheets using different schemes Scientia Iranica 24 4 1855 1865 10.24200/sci.2017.4276 Search in Google Scholar

[80] Deng, K., Pan, P., Shen, S., Wang, H., & Feng, P. (2018). Experimental study of FRP-reinforced slotted RC shear walls under cyclic loading. Journal of Composites for Construction, 22(4), 04018017. Deng K. Pan P. Shen S. Wang H. Feng P. 2018 Experimental study of FRP-reinforced slotted RC shear walls under cyclic loading Journal of Composites for Construction 22 4 04018017 10.1061/(ASCE)CC.1943-5614.0000855 Search in Google Scholar

[81] Carrillo, J., & Alcocer, S. M. (2012). Seismic performance of concrete walls for housing subjected to shaking table excitations. Engineering structures, 41, 98–107. Carrillo J. Alcocer S. M. 2012 Seismic performance of concrete walls for housing subjected to shaking table excitations Engineering structures 41 98 107 10.1016/j.engstruct.2012.03.025 Search in Google Scholar