Thin slender concrete rectangular walls in moderate seismic regions with a single reinforcement layer

Some Latin-American countries, including Colombia, Peru, Panamá and the Dominican Republic, have adopted an industrialized system for the construction of buildings using thin slender reinforced concrete walls. The main advantage of this system is that it can increase the construction speed and reduc...

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Fecha de publicación:: 2020

Institución:: Universidad de Medellín

Repositorio:: Repositorio UDEM

Idioma:: eng

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network_acronym_str	REPOUDEM2
network_name_str	Repositorio UDEM
repository_id_str
dc.title.none.fl_str_mv	Thin slender concrete rectangular walls in moderate seismic regions with a single reinforcement layer
title	Thin slender concrete rectangular walls in moderate seismic regions with a single reinforcement layer
spellingShingle	Thin slender concrete rectangular walls in moderate seismic regions with a single reinforcement layer Buckling Cyclic behavior Reinforced concrete Slender wall Thin wall Welded wire mesh Aspect ratio Axial loads Buckling Mesh generation Reinforced concrete Seismology Stochastic systems Welding Construction of buildings Cyclic behavior Performance of buildings Reinforced concrete wall Slender wall Thin walls Transverse reinforcement Welded-wire mesh Walls (structural partitions)
title_short	Thin slender concrete rectangular walls in moderate seismic regions with a single reinforcement layer
title_full	Thin slender concrete rectangular walls in moderate seismic regions with a single reinforcement layer
title_fullStr	Thin slender concrete rectangular walls in moderate seismic regions with a single reinforcement layer
title_full_unstemmed	Thin slender concrete rectangular walls in moderate seismic regions with a single reinforcement layer
title_sort	Thin slender concrete rectangular walls in moderate seismic regions with a single reinforcement layer
dc.subject.none.fl_str_mv	Buckling Cyclic behavior Reinforced concrete Slender wall Thin wall Welded wire mesh Aspect ratio Axial loads Buckling Mesh generation Reinforced concrete Seismology Stochastic systems Welding Construction of buildings Cyclic behavior Performance of buildings Reinforced concrete wall Slender wall Thin walls Transverse reinforcement Welded-wire mesh Walls (structural partitions)
topic	Buckling Cyclic behavior Reinforced concrete Slender wall Thin wall Welded wire mesh Aspect ratio Axial loads Buckling Mesh generation Reinforced concrete Seismology Stochastic systems Welding Construction of buildings Cyclic behavior Performance of buildings Reinforced concrete wall Slender wall Thin walls Transverse reinforcement Welded-wire mesh Walls (structural partitions)
description	Some Latin-American countries, including Colombia, Peru, Panamá and the Dominican Republic, have adopted an industrialized system for the construction of buildings using thin slender reinforced concrete walls. The main advantage of this system is that it can increase the construction speed and reduce the use of nonstructural walls, as all architectonical spaces are defined by the structural walls. Additionally, designers tend to use thin structural walls with low steel reinforcement ratios, which is reflected in a reduction of the construction cost. The typical wall section for 6 to 10-story buildings is characterized by a thickness of around 100 mm and a single layer of welded wire mesh acting as longitudinal and transverse reinforcement. Additional reinforcing bars may be placed at the wall edges to increase moment capacity, but in most cases, there are no confined boundary elements along the edges. Despite the system's popularity, experimental data for these types of walls is still scarse. In addition to this, structural walls of low thickness and high aspect ratio with unconfined or poorly confined boundary elements have shown structural deficiencies in the 2010 Central Valley Chile earthquake. In this paper, existing and new experimental data from representative thin slender walls, used in moderate seismic regions, was analyzed to evaluate the structural system under lateral loads. Two unconfined reinforced concrete walls with typical section detailing were tested. Additionally, these tests were complemented with an experimental database of 28 rectangular wall units of thickness less than 100 mm, as reported in the literature. This data was used to analyze the behavior of rectangular thin slender walls in terms of axial load ratio, boundary elements conditions, plastic hinge length, and maximum drift capacity. The experimental data shows a significant reduction in drift capacity as axial load, clear interstory height to wall thickness ratio, or wall length increases. It is also evident that plasticity is concentrated at the base of the walls, mainly due to the low vertical reinforcement ratios. Finally, a capacity vs. demand stochastic analysis was carried out to evaluate the performance of buildings up to 10 stories in a moderate seismic zone. These analyses show that for moderate seismic regions the probability of reaching a severe damage limit state is low for buildings configured with rectangular walls having a single layer of reinforcement. © 2019 Elsevier Ltd
publishDate	2020
dc.date.accessioned.none.fl_str_mv	2020-04-29T14:53:51Z
dc.date.available.none.fl_str_mv	2020-04-29T14:53:51Z
dc.date.none.fl_str_mv	2020
dc.type.eng.fl_str_mv	Article
dc.type.coarversion.fl_str_mv	http://purl.org/coar/version/c_970fb48d4fbd8a85
dc.type.coar.fl_str_mv	http://purl.org/coar/resource_type/c_6501 http://purl.org/coar/resource_type/c_2df8fbb1
dc.type.driver.none.fl_str_mv	info:eu-repo/semantics/article
dc.identifier.issn.none.fl_str_mv	23527102
dc.identifier.uri.none.fl_str_mv	http://hdl.handle.net/11407/5745
dc.identifier.doi.none.fl_str_mv	10.1016/j.jobe.2019.101035
identifier_str_mv	23527102 10.1016/j.jobe.2019.101035
url	http://hdl.handle.net/11407/5745
dc.language.iso.none.fl_str_mv	eng
language	eng
dc.relation.isversionof.none.fl_str_mv	https://www.scopus.com/inward/record.uri?eid=2-s2.0-85075265395&doi=10.1016%2fj.jobe.2019.101035&partnerID=40&md5=dc84d47b2e422c23320458097be687f2
dc.relation.citationvolume.none.fl_str_mv	28
dc.relation.references.none.fl_str_mv	AIS, Reglamento Colombiano de Construcción Sismo. Resistente NSR 10. (2010), Asociación Colombiana de Ingeniería Sísmica Bogotá, Colombia American Concrete Institute (ACI), (2008) Building Code Requirements for Structural Concrete and Commentary, 318. , ACI 08 Arteta, C.A., Sánchez, J., Daza, R., Pájaro, C., Blandón, C.A., Bonett, R.L., Carrillo, J., Thin Wall Reinforced Concrete Building Database for the City of Armenia (Colombia) and Testing Specimen Selection. Report 001 CEER Colombian Earthquake Engineering Research Center (2016), (Barranquilla) Arteta, C.A., Blandon, C.A., Bonett, R., Carrillo, J., Study about the Seismic Behavior of Thin Reinforced Concrete Wall Buildings: Report for Sub Committee C - AIS 100. Report 001 CEER Colombian Earthquake Engineering Research Center (2018), (Barranquilla) Jünemann, R., Hube, M., De la Llera, J.C., Kausel, E., Characteristics of reinforced concrete shear wall buildings damaged during 2010 Chile earthquake (2012) Proceedings of 15th World Conference on Earthquake Engineering, , Portugal Lisbon 2012, Paper N2265 Sritharan, S., Beyer, K., Henry, R.S., Chai, Y.H., Kowalsky, M., Bull, D., Understanding poor seismic performance of concrete walls and design implications (2014) Earthq. Spectra, 30 (1), pp. 307-334. , 2014 Alarcon, C., Hube, M.A., Junemann, R., De la Llera, J.C., Characteristics and displacement capacity of reinforced concrete walls in damaged buildings during 2010 Chile earthquake (2015) Bull. Earthq. Eng., 13 (4), pp. 1119-1139 Kam, W.Y., Pampanin, S., Elwood, K., Seismic performance of reinforced concrete buildings in the 22 February Christchurch (Lyttelton) earthquake (2011) Bull. N. Z. Soc. Earthq. Eng., 44 (4), pp. 239-278 Thomsen IV, J.H., Wallace, J.W., Displacement-based Design of Reinforced Concrete Structural Walls: an Experimental Investigation of Walls with Rectangular and T-Shaped Cross Sections. Report No. CU/CEE-95-06 (1995), Department of civil and Environmental Engineering. Clarkson University June 1995 Dazio, A., Beyer, K., Bachmann, H., Quasi-static cyclic tests and plastic hinge analysis of RC structural walls (2009) Eng. Struct., 31 (7), pp. 1556-1571 Takahashi, S., Yoshida, K., Ichinose, T., Sanada, Y., Matsumoto, K., Fukuyama, H., Suwada, H., Flexural drift capacity of reinforced concrete wall with limited confinement (2013) ACI Struct. J., 110 (1), pp. 95-104 Dai, H., An Investigation of Ductile Design of Slender Concrete Structural Walls, MS Thesis (2012), p. 134. , Iowa State University Ames. IA Lefas, I.D., Kotsovos, M.D., Ambraseys, N.N., Behavior of reinforced concrete structural walls: strength, deformation characteristics, and failure mechanism (1990) Struct. J., 87 (1), pp. 23-31 Lu, Y., Gultom, R.J., Ma, Q.Q., Henry, R.S., Experimental validation of minimum vertical reinforcement requirements for ductile concrete walls (2018) ACI Struct. J., 115 (4), pp. 1115-1130 Paulay, T., Priestley, M.J.N., Seismic Design of Reinforced Concrete and Masonry Buildings (1992), Wiley New York Rosso, A., Jiménez-Roa, L.A., de Almeida, J.P., Zuniga, A.P.G., Blandón, C.A., Bonett, R.L., Beyer, K., Cyclic tensile-compressive tests on thin concrete boundary elements with a single layer of reinforcement prone to out-of-plane instability (2018) Bull. Earthq. Eng., 16 (2), pp. 859-887 Almeida, J., Prodan, O., Rosso, A., Beyer, K., Tests on thin reinforced concrete walls subjected to in-plane and out-of-plane cyclic loading (2017) Earthq. Spectra, 33 (1), pp. 323-345. , February 2017 Quiroz, L.G., Maruyama, Y., Zavala, C., Cyclic behavior of thin RC Peruvian shear walls: full-scale experimental investigation and numerical simulation (2013) Eng. Struct., 52, pp. 153-167 Carrillo, J., Alcocer, S.M., Seismic performance of concrete walls for housing subjected to shaking table excitations (2012) Eng. Struct., 41, pp. 98-107 Hube, M.A., Marihuén, A., De la Llera, J.C., Stojadinovic, B., Seismic behavior of slender reinforced concrete walls (2014) Eng. Struct., 80, pp. 377-388 Oesterle, R.G., Fiorato, A.E., Johal, L.S., Carpenter, J.E., Russell, H.G., Corley, W.G., Earthquake Resistant Structural Walls-Tests of Isolated Walls. Research and Development Construction Technology Laboratories (1976), Portland Cement Association Thomsen IV, J.H., Wallace, J.W., Displacement-based design of slender reinforced concrete structural walls - experimental verification (2004) J. Struct. Eng., 130 (4), pp. 618-630 Su, R.K.L., Wong, S.M., Seismic behaviour of slender reinforced concrete shear walls under high axial load ratio (2007) Eng. Struct., 29 (8), pp. 1957-1965 Alarcon, C., Hube, M.A., De la Llera, J.C., Effect of axial loads in the seismic behavior of reinforced concrete walls with unconfined wall boundaries (2014) Eng. Struct., 73, pp. 13-23 Pilakoutas, K., Elnashai, A., Cyclic behavior of reinforced concrete cantilever walls, part I: experimental results (1995) ACI Struct. J., 92 (3), pp. 271-281 Goodsir, W.J., The design of coupled frame-wall structures for seismic actions (Doctoral dissertation) (1985), http://ir.canterbury.ac.nz/handle/10092/7751 McMenamin, A., The Performance of Slender Precast Reinforced Concrete Cantilever Walls with Roof Level Lateral Displacement Restraint under Simulated In-Plane Seismic Loading, Research Report 99-4 (1999), Department of Civil Engineering, University of Canterbury Christchurch, New Zealand 275pp Chiewanichakorn, M., Stability of thin precast concrete wall panels subjected to gravity and seismic forces (Doctoral dissertation) (1999), http://ir.canterbury.ac.nz/handle/10092/10450, Retrieved from Mergos, P.E., Beyer, K., Loading protocols for European regions of low to moderate seismicity (2014) Bull. Earthq. Eng., 12 (6), pp. 2507-2530 Kazaz, ?., An analytical study on the plastic hinge length of structural walls (2013) ASCE. J. Struct. Eng., 139 (11), pp. 1938-1950 Hoult, R., Goldsworthy, H., Lumantarna, E., Plastic hinge analysis for lightly reinforced and unconfined concrete structural walls (2018) Bull. Earthq. Eng., 16, pp. 4825-4860 American Concrete Institute (ACI), (2014) Building Code Requirements for Structural Concrete and Commentary, 318. , ACI 14 Hoult, R., Goldsworthy, H., Lumantarna, E., Seismic performance of lightly reinforced and unconfined C-shaped walls (2017) Australian Earthquake Engineering Society 2017 Conference, , (Canberra) Massone, L.M., Alfaro, J.I., Displacement and curvature estimation for the design of reinforced concrete slender walls (2016) Struct. Des. Tall Special Build., 25 (16), pp. 823-841 Moehle, J.P., Ghodsi, T., Hooper, J.D., Fields, D.C., Gedhada, R., Seismic Design of Cast-In-Place Concrete Special Structural Walls and Coupling Beams. NEHRP Seismic Design Technical Brief No, 6 (2011) Paulay, T., Priestley, M.J.N., Stability of ductile structural walls (1993) ACI Struct. J., 90 (4), pp. 385-392 Wallace, J.W., Moehle, J.P., Ductility and detailing requirements of bearing wall buildings (1992) J. Struct. Eng., 118 (6), pp. 1625-1644 Bonett, R., Carrillo, J., Blandon, C., Arteta, C., Restrepo, J.F., Rosales, J.L., Evaluation of ductility reduction factors for thin and slender shear walls (in Spanish). IX Congreso Nacional de Ingeniería Sísmica. Mayo 29 a 31 de 2019. Santiago de Cali. Colombia (2019) Carrillo, J., Diaz, C., Arteta, C.A., Tensile mechanical properties of the electro-welded wire meshes available in Bogotá, Colombia (2019) Constr. Build. Mater., 195, pp. 352-362 Villar-Vega, M., Silva, V., Crowley, H., Yepes, C., Tarque, N., Acevedo, A.B., Hube, M.A., Santa-María, H., Development of a Fragility Model for the Residential Building Stock in South America (2017) Earthquake Spectra, 33 (2), pp. 581-604 Silva, V., Casotto, C., Rao, A., Villar, M., Crowley, H., Vamvatsikos, D., OpenQuake Risk Modeller's Toolkit - User Guide. Global Earthquake Model. Technical Report 2015-09 (2015) McKenna, F., Fenves, G.L., Scott, M.H., Jeremic, B., Open System for Earthquake Engineering Simulation (OpenSees), Pacific Earthquake Engineering Research Center (2000), University of California Berkeley, CA McKenna, F., Scott, M.H., Fenves, G.L., Nonlinear finite element analysis software architecture using object composition (2010) J. Comput. Civ. Eng., 24
dc.rights.coar.fl_str_mv	http://purl.org/coar/access_right/c_16ec
rights_invalid_str_mv	http://purl.org/coar/access_right/c_16ec
dc.publisher.none.fl_str_mv	Elsevier Ltd
dc.publisher.program.none.fl_str_mv	Ingeniería Civil
dc.publisher.faculty.none.fl_str_mv	Facultad de Ingenierías
publisher.none.fl_str_mv	Elsevier Ltd
dc.source.none.fl_str_mv	Journal of Building Engineering
institution	Universidad de Medellín
repository.name.fl_str_mv	Repositorio Institucional Universidad de Medellin
repository.mail.fl_str_mv	repositorio@udem.edu.co
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spelling	20202020-04-29T14:53:51Z2020-04-29T14:53:51Z23527102http://hdl.handle.net/11407/574510.1016/j.jobe.2019.101035Some Latin-American countries, including Colombia, Peru, Panamá and the Dominican Republic, have adopted an industrialized system for the construction of buildings using thin slender reinforced concrete walls. The main advantage of this system is that it can increase the construction speed and reduce the use of nonstructural walls, as all architectonical spaces are defined by the structural walls. Additionally, designers tend to use thin structural walls with low steel reinforcement ratios, which is reflected in a reduction of the construction cost. The typical wall section for 6 to 10-story buildings is characterized by a thickness of around 100 mm and a single layer of welded wire mesh acting as longitudinal and transverse reinforcement. Additional reinforcing bars may be placed at the wall edges to increase moment capacity, but in most cases, there are no confined boundary elements along the edges. Despite the system's popularity, experimental data for these types of walls is still scarse. In addition to this, structural walls of low thickness and high aspect ratio with unconfined or poorly confined boundary elements have shown structural deficiencies in the 2010 Central Valley Chile earthquake. In this paper, existing and new experimental data from representative thin slender walls, used in moderate seismic regions, was analyzed to evaluate the structural system under lateral loads. Two unconfined reinforced concrete walls with typical section detailing were tested. Additionally, these tests were complemented with an experimental database of 28 rectangular wall units of thickness less than 100 mm, as reported in the literature. This data was used to analyze the behavior of rectangular thin slender walls in terms of axial load ratio, boundary elements conditions, plastic hinge length, and maximum drift capacity. The experimental data shows a significant reduction in drift capacity as axial load, clear interstory height to wall thickness ratio, or wall length increases. It is also evident that plasticity is concentrated at the base of the walls, mainly due to the low vertical reinforcement ratios. Finally, a capacity vs. demand stochastic analysis was carried out to evaluate the performance of buildings up to 10 stories in a moderate seismic zone. These analyses show that for moderate seismic regions the probability of reaching a severe damage limit state is low for buildings configured with rectangular walls having a single layer of reinforcement. © 2019 Elsevier LtdengElsevier LtdIngeniería CivilFacultad de Ingenieríashttps://www.scopus.com/inward/record.uri?eid=2-s2.0-85075265395&doi=10.1016%2fj.jobe.2019.101035&partnerID=40&md5=dc84d47b2e422c23320458097be687f228AIS, Reglamento Colombiano de Construcción Sismo. Resistente NSR 10. (2010), Asociación Colombiana de Ingeniería Sísmica Bogotá, ColombiaAmerican Concrete Institute (ACI), (2008) Building Code Requirements for Structural Concrete and Commentary, 318. , ACI 08Arteta, C.A., Sánchez, J., Daza, R., Pájaro, C., Blandón, C.A., Bonett, R.L., Carrillo, J., Thin Wall Reinforced Concrete Building Database for the City of Armenia (Colombia) and Testing Specimen Selection. Report 001 CEER Colombian Earthquake Engineering Research Center (2016), (Barranquilla)Arteta, C.A., Blandon, C.A., Bonett, R., Carrillo, J., Study about the Seismic Behavior of Thin Reinforced Concrete Wall Buildings: Report for Sub Committee C - AIS 100. Report 001 CEER Colombian Earthquake Engineering Research Center (2018), (Barranquilla)Jünemann, R., Hube, M., De la Llera, J.C., Kausel, E., Characteristics of reinforced concrete shear wall buildings damaged during 2010 Chile earthquake (2012) Proceedings of 15th World Conference on Earthquake Engineering, , Portugal Lisbon 2012, Paper N2265Sritharan, S., Beyer, K., Henry, R.S., Chai, Y.H., Kowalsky, M., Bull, D., Understanding poor seismic performance of concrete walls and design implications (2014) Earthq. Spectra, 30 (1), pp. 307-334. , 2014Alarcon, C., Hube, M.A., Junemann, R., De la Llera, J.C., Characteristics and displacement capacity of reinforced concrete walls in damaged buildings during 2010 Chile earthquake (2015) Bull. Earthq. Eng., 13 (4), pp. 1119-1139Kam, W.Y., Pampanin, S., Elwood, K., Seismic performance of reinforced concrete buildings in the 22 February Christchurch (Lyttelton) earthquake (2011) Bull. N. Z. Soc. Earthq. Eng., 44 (4), pp. 239-278Thomsen IV, J.H., Wallace, J.W., Displacement-based Design of Reinforced Concrete Structural Walls: an Experimental Investigation of Walls with Rectangular and T-Shaped Cross Sections. Report No. CU/CEE-95-06 (1995), Department of civil and Environmental Engineering. Clarkson University June 1995Dazio, A., Beyer, K., Bachmann, H., Quasi-static cyclic tests and plastic hinge analysis of RC structural walls (2009) Eng. Struct., 31 (7), pp. 1556-1571Takahashi, S., Yoshida, K., Ichinose, T., Sanada, Y., Matsumoto, K., Fukuyama, H., Suwada, H., Flexural drift capacity of reinforced concrete wall with limited confinement (2013) ACI Struct. J., 110 (1), pp. 95-104Dai, H., An Investigation of Ductile Design of Slender Concrete Structural Walls, MS Thesis (2012), p. 134. , Iowa State University Ames. IALefas, I.D., Kotsovos, M.D., Ambraseys, N.N., Behavior of reinforced concrete structural walls: strength, deformation characteristics, and failure mechanism (1990) Struct. J., 87 (1), pp. 23-31Lu, Y., Gultom, R.J., Ma, Q.Q., Henry, R.S., Experimental validation of minimum vertical reinforcement requirements for ductile concrete walls (2018) ACI Struct. J., 115 (4), pp. 1115-1130Paulay, T., Priestley, M.J.N., Seismic Design of Reinforced Concrete and Masonry Buildings (1992), Wiley New YorkRosso, A., Jiménez-Roa, L.A., de Almeida, J.P., Zuniga, A.P.G., Blandón, C.A., Bonett, R.L., Beyer, K., Cyclic tensile-compressive tests on thin concrete boundary elements with a single layer of reinforcement prone to out-of-plane instability (2018) Bull. Earthq. Eng., 16 (2), pp. 859-887Almeida, J., Prodan, O., Rosso, A., Beyer, K., Tests on thin reinforced concrete walls subjected to in-plane and out-of-plane cyclic loading (2017) Earthq. Spectra, 33 (1), pp. 323-345. , February 2017Quiroz, L.G., Maruyama, Y., Zavala, C., Cyclic behavior of thin RC Peruvian shear walls: full-scale experimental investigation and numerical simulation (2013) Eng. Struct., 52, pp. 153-167Carrillo, J., Alcocer, S.M., Seismic performance of concrete walls for housing subjected to shaking table excitations (2012) Eng. Struct., 41, pp. 98-107Hube, M.A., Marihuén, A., De la Llera, J.C., Stojadinovic, B., Seismic behavior of slender reinforced concrete walls (2014) Eng. Struct., 80, pp. 377-388Oesterle, R.G., Fiorato, A.E., Johal, L.S., Carpenter, J.E., Russell, H.G., Corley, W.G., Earthquake Resistant Structural Walls-Tests of Isolated Walls. Research and Development Construction Technology Laboratories (1976), Portland Cement AssociationThomsen IV, J.H., Wallace, J.W., Displacement-based design of slender reinforced concrete structural walls - experimental verification (2004) J. Struct. Eng., 130 (4), pp. 618-630Su, R.K.L., Wong, S.M., Seismic behaviour of slender reinforced concrete shear walls under high axial load ratio (2007) Eng. Struct., 29 (8), pp. 1957-1965Alarcon, C., Hube, M.A., De la Llera, J.C., Effect of axial loads in the seismic behavior of reinforced concrete walls with unconfined wall boundaries (2014) Eng. Struct., 73, pp. 13-23Pilakoutas, K., Elnashai, A., Cyclic behavior of reinforced concrete cantilever walls, part I: experimental results (1995) ACI Struct. J., 92 (3), pp. 271-281Goodsir, W.J., The design of coupled frame-wall structures for seismic actions (Doctoral dissertation) (1985), http://ir.canterbury.ac.nz/handle/10092/7751McMenamin, A., The Performance of Slender Precast Reinforced Concrete Cantilever Walls with Roof Level Lateral Displacement Restraint under Simulated In-Plane Seismic Loading, Research Report 99-4 (1999), Department of Civil Engineering, University of Canterbury Christchurch, New Zealand 275ppChiewanichakorn, M., Stability of thin precast concrete wall panels subjected to gravity and seismic forces (Doctoral dissertation) (1999), http://ir.canterbury.ac.nz/handle/10092/10450, Retrieved fromMergos, P.E., Beyer, K., Loading protocols for European regions of low to moderate seismicity (2014) Bull. Earthq. Eng., 12 (6), pp. 2507-2530Kazaz, ?., An analytical study on the plastic hinge length of structural walls (2013) ASCE. J. Struct. Eng., 139 (11), pp. 1938-1950Hoult, R., Goldsworthy, H., Lumantarna, E., Plastic hinge analysis for lightly reinforced and unconfined concrete structural walls (2018) Bull. Earthq. Eng., 16, pp. 4825-4860American Concrete Institute (ACI), (2014) Building Code Requirements for Structural Concrete and Commentary, 318. , ACI 14Hoult, R., Goldsworthy, H., Lumantarna, E., Seismic performance of lightly reinforced and unconfined C-shaped walls (2017) Australian Earthquake Engineering Society 2017 Conference, , (Canberra)Massone, L.M., Alfaro, J.I., Displacement and curvature estimation for the design of reinforced concrete slender walls (2016) Struct. Des. Tall Special Build., 25 (16), pp. 823-841Moehle, J.P., Ghodsi, T., Hooper, J.D., Fields, D.C., Gedhada, R., Seismic Design of Cast-In-Place Concrete Special Structural Walls and Coupling Beams. NEHRP Seismic Design Technical Brief No, 6 (2011)Paulay, T., Priestley, M.J.N., Stability of ductile structural walls (1993) ACI Struct. J., 90 (4), pp. 385-392Wallace, J.W., Moehle, J.P., Ductility and detailing requirements of bearing wall buildings (1992) J. Struct. Eng., 118 (6), pp. 1625-1644Bonett, R., Carrillo, J., Blandon, C., Arteta, C., Restrepo, J.F., Rosales, J.L., Evaluation of ductility reduction factors for thin and slender shear walls (in Spanish). IX Congreso Nacional de Ingeniería Sísmica. Mayo 29 a 31 de 2019. Santiago de Cali. Colombia (2019)Carrillo, J., Diaz, C., Arteta, C.A., Tensile mechanical properties of the electro-welded wire meshes available in Bogotá, Colombia (2019) Constr. Build. Mater., 195, pp. 352-362Villar-Vega, M., Silva, V., Crowley, H., Yepes, C., Tarque, N., Acevedo, A.B., Hube, M.A., Santa-María, H., Development of a Fragility Model for the Residential Building Stock in South America (2017) Earthquake Spectra, 33 (2), pp. 581-604Silva, V., Casotto, C., Rao, A., Villar, M., Crowley, H., Vamvatsikos, D., OpenQuake Risk Modeller's Toolkit - User Guide. Global Earthquake Model. Technical Report 2015-09 (2015)McKenna, F., Fenves, G.L., Scott, M.H., Jeremic, B., Open System for Earthquake Engineering Simulation (OpenSees), Pacific Earthquake Engineering Research Center (2000), University of California Berkeley, CAMcKenna, F., Scott, M.H., Fenves, G.L., Nonlinear finite element analysis software architecture using object composition (2010) J. Comput. Civ. Eng., 24Journal of Building EngineeringBucklingCyclic behaviorReinforced concreteSlender wallThin wallWelded wire meshAspect ratioAxial loadsBucklingMesh generationReinforced concreteSeismologyStochastic systemsWeldingConstruction of buildingsCyclic behaviorPerformance of buildingsReinforced concrete wallSlender wallThin wallsTransverse reinforcementWelded-wire meshWalls (structural partitions)Thin slender concrete rectangular walls in moderate seismic regions with a single reinforcement layerArticleinfo:eu-repo/semantics/articlehttp://purl.org/coar/version/c_970fb48d4fbd8a85http://purl.org/coar/resource_type/c_6501http://purl.org/coar/resource_type/c_2df8fbb1Blandón, C., Department of Civil Engineering, Universidad EIA, Envigado, Colombia; Bonett, R., Department of Civil Engineering, Universidad de Medellín, Colombiahttp://purl.org/coar/access_right/c_16ecBlandón C.Bonett R.11407/5745oai:repository.udem.edu.co:11407/57452020-05-27 17:52:01.735Repositorio Institucional Universidad de Medellinrepositorio@udem.edu.co

Thin slender concrete rectangular walls in moderate seismic regions with a single reinforcement layer

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