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International Journal of Steel Structures

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17-06-2022

Retrofitting of Core Reinforced Concrete Shear Wall System with Opening Using Steel Plates and FRP Sheets, A Case Study

Authors: Mohammad Meghdadian, Mansour Ghalehnovi

Published in: International Journal of Steel Structures | Issue 4/2022

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Abstract

The concrete core structures consist of a number of connected shear walls that form a tubular section. The core section might be open or closed using a series of beams or floor slabs. Therefore, this type of structures has very high moment of inertia and strength and can withstand the applied lateral loads to mid and high-rise structures a lateral load carrying system. In some cases, due to damages caused by severe ground motions or change in the use of structure or addition of new stories, the initially designed and constructed concrete core may require strengthening or rehabilitation to withstand increased applied loads or to recover the loss of strength and stiffness due to damages. A practical method to strengthened this type of structural systems is to utilize steel plates or Fiber Reinforced Polymer (FRP) sheets. The performed evaluations showed that the main components of this system that required to be strengthened are spandrels which plays role of seismic fuse for the concrete core system. This paper is a case study that evaluates effects of application of steel plates and FRP sheets on spandrels of central core concrete shear wall system for a structure that required addition of two stories after initial design. A eight-story structure with central reinforced concrete shear wall system is designed and due to a decision to add two more stories in the construction phase, the designed structure required strengthening. Since the analysis showed that only spandrels of the core system do not comply with the new strength demand, two option of using steel plates and FRP sheets for strengthening of spandrel beams were considered. The evaluation and analysis of the system under seismic loading demonstrate acceptable performance of both methods, but for the sake of economic considerations, steel plates were used in the strengthening of the structure.

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ACI Committee and International Organization for Standardization, 2019. Building code requirements for structural concrete (ACI 318-19) and commentary. American Concrete Institute.

Akhaveissy, A., et al. (2021). Numerical study on seismic behavior of composite shear walls with steel-encased profiles subjected to different axial load. Practice Periodical on Structural Design and Construction, 26(4), 04021034.CrossRef

Altin, S., Anil, Ö., Kopraman, Y., & Kara, M. E. (2013). Hysteretic behavior of RC shear walls strengthened with CFRP strips. Composites Part b: Engineering, 44(1), 321–329.CrossRef

American Institute of Steel Construction (AISC), 2016. Seismic Provisions for Structural Steel Buildings (AISC 341–16)

American Society of Civil Engineers (2010) Minimum design loads for buildings and other structures (ASCE/SEI 7-10). Reston, VA.

Antoniades, K. K., Salonikios, T. N., & Kappos, A. J. (2003). Cyclic tests on seismically damaged reinforced concrete walls strengthened using fiber-reinforced polymer reinforcement. ACI Structural Journal, 100(4), 510–518.

Arabshahi, A., et al. (2022). Prediction of the effective moment of inertia for concrete beams reinforced with FRP bars using an evolutionary algorithm. Structures, 35, 684–705.CrossRef

Arabzadeh, H., & Galal, K. (2017). Seismic collapse risk assessment and FRP retrofitting of RC coupled C-shaped core walls using the FEMA P695 methodology. Journal of Structural Engineering, 143(9), 04017096.CrossRef

Arabzadeh, H., & Galal, K. (2018). Seismic-response analysis of RC C-shaped core walls subjected to combined flexure, shear, and torsion. Journal of Structural Engineering, 144(10), 04018165.CrossRef

ASCE (American Society of Civil Engineers), 2016. Minimum design loads and associated criteria for buildings and other structures. ASCE standard ASCE/SEI 7–16 (in preparation). Reston, VA: American Society of Civil Engineers.

Bamshad, O., & Ghassemieh, M. (2020). Development of modified Ibarra-Krawinkler deterioration model for one-story steel plate shear wall. International Journal of Steel Structures, 20(5), 1730–1754.CrossRef

Bažant, Z. (1999). Size effect on structural strength: A review. Archive of Applied Mechanics, 69, 703–725.MATHCrossRef

Behfarnia, K. and Sayah, A.R., (2012) FRP strengthening of shear wallswith openings.

Behfarnia, K., & Shirneshana, A. (2017). A numerical study on behavior of CFRP strengthened shear wall with opening. Comput Concrete, 19(2), 179–189.CrossRef

Beyer, K., Dazio, A., & Priestley, M. J. N. (2008b). Quasi-static cyclic tests of two U-shaped reinforced concrete walls. Journal of Earthquake Engineering, 12(7), 1023–1053.CrossRef

Beyer, K., Dazio, A. and Priestley, M.N., (2008a). Seismic design of torsionally eccentric buildings with U-shaped RC walls (No. REP_WORK). IUSS Press.

Boivin, Y., & Paultre, P. (2010). Seismic performance of a 12-storey ductile concrete shear wall system designed according to the 2005 National building code of Canada and the 2004 Canadian Standard Association standard A23.3. Canadian Journal of Civil Engineering, 37(1), 1–16.CrossRef

Carrillo, J., & Alcocer, S. M. (2012). Acceptance limits for performance-based seismic design of RC walls for low-rise housing. Earthquake Engineering & Structural Dynamics, 41(15), 2273–2288.

Chen, Z., Liang, Y., Liu, X., & Cai, J. (2021). Experimental study on the hysteresis behavior of L-shaped double-skin composite wall with concrete-filled steel tubes. Engineering Structures, 245, 112965.CrossRef

Colotti, V. (1993). Shear behavior of RC structural walls. Journal of Structural Engineering, 119(3), 728–746.CrossRef

Constantin, R.T. and Beyer, K., (2012) Modelling of reinforced concrete core walls under bi-directional loading. In proceedings of the 15th World conference on earthquake engineering (No. CONF).

CSA (Canadian Standards Association). (2004). “Design of concrete structures.” CSA A23.3-04, Rexdale, ON, Canada.

CSA (Canadian Standards Association). (2014). “Design of concrete structures.” CSA A23.3-14, Rexdale, ON, Canada.

El-Tawil, S., Harries, K. A., Fortney, P. J., Shahrooz, B. M., & Kurama, Y. (2010). Seismic design of hybrid coupled wall systems: State of the art. Journal of Structural Engineering, 136(7), 755–769.CrossRef

Elwood, K.J., (2004) Shake table tests and analytical studies on the gravity load collapse of reinforced concrete frames.

Eom, T. S., et al. (2009). Behavior of double skin composite wall subjected to in-plane cyclic loading. Journal of Structural Engineering, 135(10), 1239–1249.CrossRef

Eurocode, C.E.N., (2004) 8: Design of structures for earthquake resistance-Part 1: General rules, seismic actions and rules for buildings, EN 1998-1. European Committee for Standardization, Bruxelles.

Farhidzadeh, A., Salamone, S., Luna, B., & Whittaker, A. (2013). Acoustic emission monitoring of a reinforced concrete shear wall by b-value–based outlier analysis. Structural Health Monitoring, 12(1), 3–13.CrossRef

Fischinger, M., Rejec, K. and Isaković, T., (2012) Modeling inelastic shear response of RC walls. In proceedings, 15th world conference on earthquake engineering (Vol. 2120).

Foraboschi, P. (2019). Lateral load-carrying capacity of steel columns with fixed-roller end supports. Journal of Building Engineering, 26, 100879.CrossRef

Ghalehnovi, M., Roshan, N., Hakak, E., Shamsabadi, E. A., & De Brito, J. (2019). Effect of red mud (bauxite residue) as cement replacement on the properties of self-compacting concrete incorporating various fillers. Journal of Cleaner Production, 240, 118213.CrossRef

Ghalehnovi, M., et al. (2020). Investigation of the behaviour of steel-concrete-steel sandwich slabs with bi-directional corrugated-strip connectors. Applied Sciences, 10(23), 8647.CrossRef

Ghalehnovi, M., et al. (2022). Production of environmentally friendly concrete incorporating bauxite residue and silica fume. Journal of Materials in Civil Engineering, 34(2), 04021423.CrossRef

Ghobarah, A. and Khalil, A.A., (2004) August. Seismic rehabilitation of reinforced concrete walls using fibre composites. In proceedings of the 13th world conference on earthquake engineering, Vancouver, BC, Canada, August (pp. 1–6).

Ghorbanirenani, I., Tremblay, R., Léger, P., & Leclerc, M. (2012). Shake table testing of slender RC shear walls subjected to eastern North America seismic ground motions. Journal of Structural Engineering, 138(12), 1515–1529.CrossRef

Han, J., Shu, G., Qin, Y., Zhou, G., & Zhou, X. (2021). Experimental seismic behavior of double skin composite wall with steel truss. Journal of Constructional Steel Research, 180, 106569.CrossRef

Hawileh, R. A., Musto, H. A., Abdalla, J. A., & Naser, M. Z. (2019). Finite element modeling of reinforced concrete beams externally strengthened in flexure with side-bonded FRP laminates. Composites Part b: Engineering, 173, 106952.CrossRef

Hossain, K. M., Rafiei, S., Lachemi, M., Behdinan, K., & Anwar, M. S. (2016). Finite element modeling of impact shear resistance of double skin composite wall. Thin-Walled Structures, 107, 101–118.CrossRef

Houshmand-Sarvestani, A., et al. (2021). Numerical assessment of the effects of ADAS yielding metallic dampers on the structural behavior of steel shear walls (SSWs). Mechanics Based Design of Structures and Machines. https://doi.org/10.1080/15397734.2021.1875328CrossRef

Hu, Y., et al. (2020). Cyclic performance of concrete-filled double-skin steel tube frames strengthened with beam-only-connected composite steel plate shear walls. Journal of Building Engineering, 31, 101376.CrossRef

Hu, Y., Zhao, J., Zhang, D., & Zhang, H. (2020a). Cyclic tests of fully prefabricated concrete-filled double-skin steel tube/moment-resisting frames with beam-only-connected steel plate shear walls. Thin-Walled Structures, 146, 106272.CrossRef

Hu, Y., Zhao, J., Zhang, D., & Li, Y. (2020b). Cyclic performance of concrete-filled double-skin steel tube frames strengthened with beam-only-connected composite steel plate shear walls. Journal of Building Engineering, 31, 101376.CrossRef

Huang, Z., & Liew, J. Y. R. (2016). Experimental and analytical studies of curved steel–concrete–steel sandwich panels under patch loads. Materials & Design, 93, 104–117.CrossRef

Huang, Z., & Liew, J. Y. R. (2016). Steel-concrete-steel sandwich composite structures subjected to extreme loads. Int J Steel Struct, 16, 1009–1028.CrossRef

Huang, Z., et al. (2019). Experimental behavior of VHSC encased composite stub column under compression and end moment. Steel and Composite Structures, 31(1), 69–83.

Huang, Z., et al. (2020). Experimental investigation and damage simulation of large-scaled filament wound composite pipes. Composites Part B Engineering, 184, 107639.CrossRef

Hwang, S.J., Tu, Y.S., Yeh, Y.H. and Chiou, T.C., (2004) Reinforced concrete partition walls retrofitted with carbon fiber reinforced polymer. In ANCER annual meeting: Networking of young earthquake engineering researchers and professionals.

Ile, N., & Reynouard, J. M. (2005). Behaviour of U-shaped walls subjected to uniaxial and biaxial cyclic lateral loading. Journal of Earthquake Engineering, 9(01), 67–94.

Jiang, H., & Kurama, Y. C. (2010). Analytical modeling of medium-rise reinforced concrete shear walls. ACI Structural Journal. https://doi.org/10.14359/51663812CrossRef

Jin, S., et al. (2022). Experimental and numerical investigation of assembled multi-grid corrugated steel plate shear walls. Engineering Structures, 251, 113544.CrossRef

Kisa, M. H., Yuksel, S. B., & Caglar, N. (2021). Experimental study on hysteric behavior of composite shear walls with steel sheets. Journal of Building Engineering, 33, 101570.CrossRef

Kolozvari, K., 2013. Analytical modeling of cyclic shear-flexure interaction in reinforced concrete structural walls (Doctoral dissertation, UCLA).

Kordzangeneh, G., et al. (2021). Experimental cyclic performance of steel shear walls with single rectangular opening. The Structural Design of Tall and Special Buildings, 30(2), e1821.CrossRef

Li, J., et al. (2022). Experimental and numerical study on the seismic performance of an L-shaped double-steel plate composite shear wall. Journal of Building Engineering, 49, 104015.CrossRef

Lombard, J., Lau, D.T., Humar, J.L., Foo, S. and Cheung, M.S., (2000) Seismic strengthening and repair of reinforced concrete shear walls. In proceedings 12th world conference on earthquake engineering.

Lowes, L., Lehman, D., Kuchma, D., Mock, A. and Behrouzi, A., (2013). Large scale tests of C-shaped reinforced concrete walls. Summary report from NEES project warehouse. Available at https://nees.org/warehouse/project/104.

Lu, Y. and Panagiotou, M., (2012) Three-dimensional nonlinear cyclic beam-truss model for non-planar reinforced concrete walls. Rep. UCB/SEMM-2012, 1.

Man, H. K., & van Mier, J. G. M. (2008). Size effect on strength and fracture energy for numerical concrete with realistic aggregate shapes. International Journal of Fracture, 154, 61–72.MATHCrossRef

Meghdadaian, M. and Ghalehnovi, M., (2022) Proposition of design relations for composite steel plate shear walls containing an opening.

Meghdadaian, M., & Ghalehnovi, M. (2019). Improving seismic performance of composite steel plate shear walls containing openings. Journal of Building Engineering, 21, 336–342.CrossRef

Meghdadian, M. (2019). Effects of the opening on the behavior of composite steel plate shear wall (CSPSW). Journal of Rehabilitation in Civil Engineerin, 7(3), 139–152.

Meghdadian, M., Gharaei-Moghaddam, N., Arabshahi, A., Mahdavi, N., & Ghalehnovi, M. (2020). Proposition of an equivalent reduced thickness for composite steel plate shear walls containing an opening. Journal of Constructional Steel Research, 168, 105985.CrossRef

Meghdadian, M., Masoodi, A., & Ghalehnovi, M. (2022). Nonlinear seismic analysis of composite coupled shear walls strengthened by CFRP sheets. SSRN Journal. https://doi.org/10.2139/ssrn.4023113CrossRef

Meghdadian, M., Arabshahi, A., Aghouy, (2020a), Parametric study of the influential factors on the ultimate capacity of composite steel plate shear walls with opening. In international congress on civil engineering, architecture and urban sustainable development in Asia, Tokyo – Japan

Meghdadian, M., Arabshahi, A., Gharaei Moghaddam, N., & Tavakkolizadeh, M. (2020b). Predictive model for confinement pressure of partially FRP confined concrete columns. In 12th national congress on civil engineering, Sahand University of Technology

Meghdadian, M., Arabshahi, A., Aghouy, S. R., & Gharaei-Moghaddam, N., (2020b). Evaluation of the bond strength models between fiber reinforced polymers and concrete. In international conference on civil engineering, architecture, development and reconstruction of urban infrastructure in IRAN, Tehran.

Meghdaidan, M., Gharaei-Moghaddam, N., and Ghalehnovi, M., A state-of-the-art review on the concrete-encased composite shear walls (2022).

Mohammed, B. S., Ean, L. W., & Malek, M. A. (2013). One way RC wall panels with openings strengthened with CFRP. Construction and Building Materials, 40, 575–583.CrossRef

Mohsenian, V., Hajirasouliha, I., Mariani, S., & Nikkhoo, A. (2020). Seismic reliability assessment of RC tunnel-form structures with geometric irregularities using a combined system approach. Soil Dynamics and Earthquake Engineering, 139, 106356.CrossRef

Mohsenian, V., Gharaei-Moghaddam, N., & Hajirasouliha, I. (2021). Response modification factors for dual moment-resisting frames with vertical links: Multilevel approach. Advances in Structural Engineering, 24(14), 3299–3314.CrossRef

Mohsenian, V., Gharaei-Moghaddam, N., & Hajirasouliha, I. (2022). An innovative variable target time method for probabilistic-based seismic performance assessment of 3D multi-storey buildings. Journal of Building Engineering, 52, 104378.CrossRef

Mortezaei, A., & Mohsenian, V. (2019). Reliability-based seismic assessment of multi-story box system buildings under the accidental torsion. Journal of Earthquake Engineering, 26(2), 674–679.CrossRef

Mosallam, A. S., & Nasr, A. (2017). Structural performance of RC shear walls with post-construction openings strengthened with FRP composite laminates. Composites Part b: Engineering, 115, 488–504.CrossRef

Mullapudi, R. T., & Ayoub, A. S. (2009). Fiber beam element formulation using the softened membrane model. Special Publication, 265, 283–308.

Munesi, A., Majid, G., & Mohammadkazem, S. (2020). Numerical study on seismic behaviour of buckling-restrained steel plate shear walls. Proceedings of the Institution of Civil Engineers-Structures and Buildings. https://doi.org/10.1680/jstbu.19.00214CrossRef

Munesi, A., Sharbatdar, M., & Gholhaki, M. (2021). An investigation into the factors influencing the cyclic behaviour of buckling-restrained steel plate shear walls. Steel Construction, 14(1), 35–46.CrossRef

National Research Council of Canada. (2010) National building code of Canada, Ottawa, ON.

NBCC (National Building Code of Canada). (2005). National research council of Canada, Ottawa

Panagiotou, M., & Restrepo, J. I. (2011). Nonlinear cyclic truss model for strength degrading reinforced concrete plane stress elements. University of California.

Pelletier, K., & Léger, P. (2017). Nonlinear seismic modeling of reinforced concrete cores including torsion. Engineering Structures, 136, 380–392.CrossRef

Popescu, C., Sas, G., Blanksvärd, T., & Täljsten, B. (2015). Concrete walls weakened by openings as compression members: A review. Engineering Structures, 89, 172–190.CrossRef

Qin, Y., Shu, G. P., Fan, S. G., Lu, J. Y., Cao, S., & Han, J. H. (2017). Strength of double skin steel-concrete composite walls. International Journal of Steel Structures, 17(2), 535–541.CrossRef

Rafiei, S., Hossain, K. M., Lachemi, M., & Behdinan, K. (2017). Impact shear resistance of double skin profiled composite wall. Engineering Structures, 140, 267–285.CrossRef

Sabouri-Ghomi, S., et al. (2022). In-plane deformation of stiffeners around opening in steel shear panels. International Journal of Civil Engineering, 20(6), 661–689.CrossRef

Sabzi, J., et al. (2021). Mechanical and durability properties of mortars incorporating red mud, ground granulated blast furnace slag, and electric arc furnace dust. Applied Sciences, 11(9), 4110.CrossRef

Sas, G., Demeter, I., Nagy-György, T., Stoian, V., Carolin, A. and Täljsten, B., (2008) FRP strengthened RC panels with cut-out openings. In Challenges for Civil Construction: 16/05/2008–18/05/2008. FEUP edições (Faculdade de Engenharia da Universidade do Porto Edicoes).

Shamsabadi, E. A., et al. (2022). Machine learning-based compressive strength modelling of concrete incorporating waste marble powder. Construction and Building Materials, 324, 126592.CrossRef

Shi, K., et al. (2021). Seismic behavior of steel-fiber-reinforced high-strength concrete shear wall with CFST columns: Experimental investigation. Fibers, 9(11), 75.CrossRef

Shi, J., Gao, S., & Guo, L. (2021). Compressive behaviour of double skin composite shear walls stiffened with steel-bars trusses. Journal of Constructional Steel Research, 180, 106581.CrossRef

Shi, J., Guo, L., & Qu, B. (2022). In-plane cyclic tests of double-skin composite walls with concrete-filled steel tube boundary elements. Engineering Structures, 250, 113301.CrossRef

Sobhani, E., et al. (2022). Multifunctional trace of various reinforcements on vibrations of three-phase nanocomposite combined hemispherical-cylindrical shells. Composite Structures, 279, 114798.CrossRef

Vecchio, F. J., & Collins, M. P. (1986). The modified compression-field theory for reinforced concrete elements subjected to shear. ACI Journal, 83(2), 219–231.

Vulcano, A., Bertero, V.V. and Colotti, V., (1988) Analytical modeling of RC structural walls. In proceedings, 9th world conference on earthquake engineering (Vol. 6, pp. 41–46).

Wang, Gu. Q., & Qi, Y. (2022). Thickness demand for concrete panel in design of C-PSW/CE under cyclic loading. Journal of Building Engineering, 48, 104011.CrossRef

Xiao, C., et al. (2021). Experimental study on seismic performance of embedded steel plate-HSC composite shear walls. Journal of Building Engineering, 34, 101909.CrossRef

Yan, J. B., Li, Z. X., & Wang, T. (2018). Seismic behaviour of double skin composite shear walls with overlapped headed studs. Construction and Building Materials, 191, 590–607.CrossRef

Yousefi, M., Khandestani, R., & Gharaei-Moghaddam, N. (2022). Flexural behavior of reinforced concrete beams made of normal and polypropylene fiber-reinforced concrete containing date palm leaf ash. Structures, 37, 1053–1068.CrossRef

Zhang, J., & Xu, S. Y. (2009). Seismic response simulations of bridges considering shear-flexural interaction of columns. Structural Engineering and Mechanics, 31(5), 545–566.CrossRef

Zhao, C., et al. (2021). Blast behavior of steel-concrete-steel sandwich panel: Experiment and numerical simulation. Engineering Structures, 246, 112998.CrossRef

Title: Retrofitting of Core Reinforced Concrete Shear Wall System with Opening Using Steel Plates and FRP Sheets, A Case Study
Authors: Mohammad Meghdadian
Mansour Ghalehnovi
Publication date: 17-06-2022
Publisher: Korean Society of Steel Construction
Published in: International Journal of Steel Structures / Issue 4/2022
Print ISSN: 1598-2351
Electronic ISSN: 2093-6311
DOI: https://doi.org/10.1007/s13296-022-00614-1

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