Increasing the strength of existing building using steel jacketing in seismic zone

Rawat, Vijay Singh

doi:10.14445/23488352/ijce-v4i12p102

Cited by 2 publications

(5 citation statements)

References 4 publications

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“…I s is the moment of inertia of the steel shape about the elastic neutral axis of the composite section, I sr is the moment of inertia of the reinforcing bars about the elastic neutral axis of the composite section, and I c is the moment of inertia of the concrete section about the elastic neutral axis of the composite section. C 1 is the coefficient for calculation of effective rigidity of an encased composite compression member, computed using equation (5).…”

Section: Prediction Of the Compressive Strength Of Columnsmentioning

confidence: 99%

“…Structural and non-structural damages and poor performance of RC buildings with code non-compliances have been observed after recent earthquakes [3]. Most of these damages haven been evidenced in RC columns with insufficient axial/shear loads capacity given by inadequate longitudinal/transversal reinforcement and dimensions, 90-degree hooks for stirrups at both ends of columns, inadequate detailing in beam-column joint regions, strong-beam and weak-columns, soft stories, weak stories, and poor quality construction [4,5].…”

Section: Introductionmentioning

confidence: 99%

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Performance evaluation of structures with reinforced concrete columns retrofitted with steel jacketing

Villar-Salinas

Guzmán

Carrillo

2021

Journal of Building Engineering

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Section: Prediction Of the Compressive Strength Of Columnsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Performance evaluation of structures with reinforced concrete columns retrofitted with steel jacketing

Villar-Salinas

Guzmán

Carrillo

2021

Journal of Building Engineering

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“…The breach of actual seismic codes and standards by several existing buildings has been noticed and studied by some authors worldwide (Abou-Elfath et al, 2017;Domínguez et al, 2016;Falcone et al, 2019;López-Almansa et al, 2013;Miano et al, 2022;Quintana Gallo et al, 2022;Requena-Garcia-Cruz et al, 2022;Tena-Colunga et al, 2022), and accordingly, the collapse risk of these buildings against earthquake occurrence (Aboutaha et al, 1999;Alfarah et al, 2020;Pampanin & Akguzel, 2011;Ricci et al, 2011;Singh Rawat, 2017) has also been noticed. Furthermore, there are RC columns in Moment-Resisting Frame (MRF) buildings having such high ACR values that undergo excessive DCR, still for vertical loads, as reported by a recent study (Villar-Salinas et al, 2021).…”

Section: Introduction To This Sectionmentioning

confidence: 99%

“…For the purpose of retrofitting, the RC columns in MRF buildings with excessive DCR under service loads shall be provided with additional compressive strength as a priority, avoiding eventual demolitions and deformations of the existing structures during retrofitting, to secure the structural integrity and safety (Villar-Salinas et al, 2021). There are diverse retrofitting techniques like the addition of steel bracings (Nateghi-A, 1995), the adding of infill walls (Willam et al, 2010), jacketing with fiber reinforced polymers (FRP) (Abdelkerim et al, 2019;Al-Mahaidi & Kalfat, 2018;Azarm et al, 2017) or steel jacketing (Aboutaha et al, 1999;Islam & Hoque, 2015;Singh Rawat, 2017). However, some methods require axial deformation of columns to fully activate the confinement action (for instance, the jacketing with FRP) or require the construction of additional foundation or space availability, which are not feasible in most of the cases.…”

Section: Introduction To This Sectionmentioning

confidence: 99%

“…However, some methods require axial deformation of columns to fully activate the confinement action (for instance, the jacketing with FRP) or require the construction of additional foundation or space availability, which are not feasible in most of the cases. The compressive, shear and the monotonic or hysteretic deformation (González Cuevas et al, 2007;Singh Rawat, 2017;) capacity of individual retrofitted RC columns and isolated structures have been studied in the last decades. The retrofitting scheme for columns and joints proposed by Villar-Salinas et al ( 2021) is described in subsection 3.3.2.…”

Section: Introduction To This Sectionmentioning

confidence: 99%

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Influence of axial compression ratio in building columns

Villar Salinas

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(English) Axial forces in columns of moment-resisting frames (MRF) have a paramount role for the seismic performance of these structural systems. Nonetheless, there are significant gaps in the literature entailing the influence of these forces in the seismic performance of MRF. Some of these gaps are: (i) there are poorly designed Reinforced Concrete (RC) columns of actual MRF buildings which can undergo Axial Compression Ratios (ACR) so high as their demand exceeds their capacity, even for only serviceability gravity load combinations; this lack commonly leads to insufficient seismic strength. Nonetheless, many seismic design codes do not specify limits for ACR, (ii) Existing design philosophies for the design of Exposed Column Base Plates (ECBP), fail to accurately predict the failure modes of these column-base connections; besides, these philosophies does not account for the moment-axial loads interaction in the components of these connections, (iii) there is a lack of reliable predictive models for the modelling parameters of ECBP subjected to moment and axial loads. In order to investigate these problems, this research aims to: (i) preliminary investigate relationships between the ACR and seismic performance indicators (e.g., inter-story drifts and demandcapacity ratios of columns in MRF). Three prototype 6 and 11-story RC MRF buildings are analyzed; these buildings have columns undergoing excessive ACR, according to the limits prescribed by standards. The original prototype buildings are modified through three different methods to reduce the ACR; then, code-type and pushover analyses are performed on the original and retrofitted buildings; the suitability of the other modified buildings is checked by code-type analyses only. (ii) present a new approach for the uniaxial moment-axial force interaction in the strong direction of columns of low-rise MRF. The derived approach is applied to three specimens designed according the American and European documents; such specimens represent small, medium and large sections. These analytical results are satisfactorily compared with a finite element analysis; this endorses the accuracy of the proposed formulation. (iii) provide predictive equations to estimate the various parameters defining nonlinear response of ECBP; their efficacy is examined against test data. A database and an associated tool were developed to characterize the modelling parameters of ECBP subjected to flexure and axial compression. A trilinear model was adopted to represent various phases of nonlinear response. (Català) Les forces internes axials en columnes de pòrtics-resistents a moment (MRF, per les sigles en anglès) tenen un rol fonamental en l'exercici sísmic d'aquests sistemes estructurals. No obstant això, hi ha bretxes significatives en la literatura relacionades amb la influència d'aquestes forces en l'exercici sísmic d'aquests pòrtics. Algunes d'aquestes bretxes són: (i) Hi ha columnes en edificis de concret reforçat (RC, per les sigles en anglès) dissenyades deficientment, de manera que la seva demanda excedeix la seva capacitat, fins i tot per a combinacions de càrregues gravitacionals de servei; aquesta deficiència normalment condueix a una resistència sísmica insuficient. Tot i això, molts codis de disseny sísmic no especifiquen límits per a la relació de forces axials (ACR, per les sigles en anglès), (ii) Les filosofies de disseny existents per al disseny de platines de base exposades (ECBP, per les sigles en anglès), fallen a predir de forma precisa els modes de falla d'aquestes connexions columnasbase; a més, aquestes filosofies no consideren la interacció moment-càrrega axial per a cada component d'aquestes connexions, (iii) Fan falta models predictius fiables per als paràmetres de modelació d'ECPP sotmeses a moment i càrrega axial. Amb per tal d'investigar aquests problemes, els objectius de la present tesi són: (i) investigar preliminarment la relació existent entre l'ACR i alguns indicadors d'acompliment sísmic (per exemple, les derives de pis i les relacions demanda-capacitat). Tres edificis de 6 i 11 pisos, de MRF de RC són analitzats; aquests edificis tenen columnes amb ACR excessiu, dacord amb els estàndards. Els edificis prototipus originals són modificats a través de tres mètodes diferents per reduir l'ACR; llavors, anàlisis modals i pushover es van realitzar sobre els edificis originals i reforçats; la viabilitat dels altres edificis modificats es va verificar a través d'anàlisis modals únicament. (ii) presentar un nou enfocament per a la interacció “moment uniaxial-càrregues axials” a la direcció forta de les columnes d'edificis baixos de MRF en acer. L'enfocament derivat s'aplica a tres espècimens dissenyats conforme a les regulacions europees i americanes; aquests espècimens representen seccions petites, mitjanes i grans. Aquests resultats analítics són comparats satisfactòriament amb els resultats d'una anàlisi pel “mètode dels elements finits”; aquesta comparació dóna suport a la precisió de la formulació proposada. (iii) proveir equacions per predir els paràmetres per definir la resposta no-lineal d'ECPP; la seva eficàcia és examinada contra dades de experimentals. Una base de dades i una eina en base web va ser desenvolupada per caracteritzar els paràmetres de modelació de ECBP sotmeses a moment i força axial de compressió. Un model trilineal va ser adoptat per representar totes les fases de la resposta no-lineal de les connexions. (Español) Las fuerzas internas axiales en columnas de pórticos-resistentes a momento (MRF, por sus siglas en inglés) tienen un rol fundamental en el desempeño sísmico de estos sistemas estructurales. No obstante, existen brechas significativas en la literatura relacionadas con la influencia de estas fuerzas en el desempeño sísmico de estos pórticos. Algunas de estas brechas son: (i) Existen columnas en edificios de concreto reforzado (RC, por sus siglas en inglés) diseñadas deficientemente, de tal forma que su demanda excede su capacidad, incluso para combinaciones de cargas gravitacionales de servicio; esta deficiencia normalmente conduce a una resistencia sísmica insuficiente. A pesar de esto, muchos códigos de diseño sísmico no especifican límites para la relación de fuerzas axiales (ACR, por sus siglas en inglés), (ii) Las filosofías de diseño existentes para el diseño de platinas de base expuestas (ECBP, por sus siglas en inglés), fallan en predecir de forma precisa los modos de falla de estas conexiones columnasbase; además, estas filosofías no consideran la interacción momento-carga axial para cada componente de dichas conexiones, (iii) Hacen falta modelos predictivos confiables para los parámetros de modelación de ECBP sometidas a momento y carga axial. Con el fin de investigar estos problemas, los objetivos de la presente tesis son: (i) investigar preliminarmente la relación existente entre la ACR y algunos indicadores de desempeño sísmico (por ejemplo, las derivas de piso y las relaciones demanda-capacidad). Tres edificios de 6 y 11 pisos, de MRF de RC son analizados; estos edificios tienen columnas con ACR excesivo, de acuerdo con los estándares. Los edificios prototipo originales son modificados a través de tres métodos diferentes para reducir el ACR; entonces, análisis modales y pushover se realizaron sobre los edificios originales y reforzados; la viabilidad de los otros edificios modificados se verificó a través de análisis modales únicamente. (ii) presentar un nuevo enfoque para la interacción “momento uniaxial-cargas axiales” en la dirección fuerte de las columnas de edificios bajos de MRF en acero. El enfoque derivado se aplica a tres especímenes diseñados conforme a las regulaciones europeas y americanas; tales especímenes representan secciones pequeñas, medianas y grandes. Estos resultados analíticos son comparados satisfactoriamente con los resultados de un análisis por el “método de los elementos finitos”; esta comparación respalda la precisión de la formulación propuesta. (iii) proveer ecuaciones para predecir los parámetros para definir la respuesta no-lineal de ECBP; su eficacia es examinada contra datos de experimentales. Una base de datos y una herramienta en base web fue desarrollada para caracterizar los parámetros de modelación de ECBP sometidas a momento y fuerza axial de compresión. Un modelo tri-lineal fue adoptado para representar todas las fases de la respuesta no-lineal de las conexiones.

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Increasing the strength of existing building using steel jacketing in seismic zone

Cited by 2 publications

References 4 publications

Performance evaluation of structures with reinforced concrete columns retrofitted with steel jacketing

Performance evaluation of structures with reinforced concrete columns retrofitted with steel jacketing

Influence of axial compression ratio in building columns

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