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A comparative study of the seismic base shear force and story drift ratios using Time History and Modal Spectrum Analysis according to Peru Code E.030 and ASCE 7.16 on high-rise buildingsQuezada Ramos, Eder Nel, Serrano Arone, Yaneth, Huaco, Guillermo 30 September 2020 (has links)
El texto completo de este trabajo no está disponible en el Repositorio Académico UPC por restricciones de la casa editorial donde ha sido publicado. / Since the last decade there is an important increase of high-rise buildings in Peru, especially in urban areas. Therefore, it is necessary to assess if the Peruvian Seismic Code is applicable for this type of buildings which have long natural periods as their main characteristic. The main objective of this article is to compare the results of the base shear and story drift ratios of Peruvian seismic design code E.030 with those of the ASCE 7-16 standard to the case of high-rise buildings, this due to the fact that there is limited information for tall buildings in Peru or comparison between national or international code for this type of structures. These high rise buildings have square and rectangular plan floors. Half of them have moment frames and reinforce concrete slab around the rigid core and the others have post-tensioned slab as their vertical load resisting system and central core walls with peripheral columns as the lateral force resisting system. Hence, the response spectrum analysis (RSA) is carried out for every case of the four tall buildings with different configurations using both seismic codes. Then results are compared with the linear response history analysis (LRHA) considering five Peruvian ground motions records, which were scaled to 0.45g PGA. It was verified that generally both the base shear and the interstory drifts calculated using ASCE7-16 are less than that obtained with the seismic code E.030.
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Dynamic Amplification Factor Proposal for Seismic Resistant Design of Tall Buildings with Rigid Core Structural SystemQuezada, Eder, Serrano, Yaneth, Huaco, Guillermo 01 January 2021 (has links)
El texto completo de este trabajo no está disponible en el Repositorio Académico UPC por restricciones de la casa editorial donde ha sido publicado. / Currently, there is an increase in the demand for tall buildings in the city of Lima. This research proposes to reduce the dynamic amplification factor through the seismic design of tall buildings based on the requirements of Peruvian code considering that they are regular in plan and height. Minimum base shear values according to the comparison of static seismic shear and dynamic shear from the spectral modal analysis were reviewed for cases of buildings larger than 120 m. The study of 28 reinforced concrete buildings was proposed, with different heights - varying from 24 to 36 floors, with different floor configurations, as well as the arrangement of the walls considering as a rigid core structural system. Additionally, the characteristics of the materials, the loads and combinations were defined. The responses of these buildings were determined by the response spectrum analysis (RSA) and then compared with those obtained by the lineal response history analysis (LRHA), for the last analysis, five Peruvian seismic records were used and scaled to 0.45 g. The seismic responses of the LRHA procedure were taken as a benchmark. The result of this study is the analysis and proposal of the C/R factor for high-rise buildings, as well as obtaining the base shear and drift verification. Minimum base shear values can be reduced for high or long-term buildings, being regular in plan and height. / Revisión por pares
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Comparación de la vulnerabilidad sísmica de edificios de concreto armado de 35 pisos con núcleo rígido, con amortiguadores de fluido viscoso y disipadores SLB, mediante el análisis modal pushover en la ciudad de Lima / Comparison of the seismic vulnerability of 35-story reinforced concrete buildings with a rigid core, with viscous fluid dampers and SLB dissipators, using pushover modal analysis in Lima cityArita Claros, Luis Humberto, Lezameta Navarro, Rodrigo André 15 January 2021 (has links)
Actualmente en la ciudad de Lima existe un número limitado de edificios de gran altura. Por lo que no existe mucha literatura de este tipo de edificaciones en Perú. Los códigos peruanos se enfocan en edificios de mediana y baja altura. Por ello, se requiere realizar estudios más detallados para analizar y diseñar de forma más adecuada estas edificaciones altas según la realidad del país. En el presente artículo, se desarrollará el análisis modal pushover a 6 tipos de edificaciones de concreto armado de 35 niveles en la ciudad de Lima.
Se plantea 3 modelos de edificación con distinto sistema estructural y con diferentes plantas (cuadrada y rectangular), siendo las áreas de 29m x 29m y 52m x 26m respectivamente. Estos sistemas estructurales son de núcleo rígido y pórticos con sistema de disipación de energía (amortiguadores de fluido viscoso y disipadores SLB) con objetivo de estudiar su comportamiento frente a solicitaciones sísmicas. Estas edificaciones se establecieron en función de los criterios y requerimientos de los códigos vigentes en el país, como también, distribución de la planta de edificaciones comúnmente usadas para oficinas y viviendas.
Se encontró que los periodos naturales oscilan entre 2.6 a 3.3 segundos para edificios de núcleo rígido, se presenta un incremento para los edificios de amortiguamiento viscoso de 4.2 a 5.4 segundos y también para los de dispositivos SLB oscilan en un rango de 3.7 a 4.6 segundos. Se realizó, a su vez, un análisis no lineal estático modal para obtener las curvas de capacidad para cada tipo de edificación, las cuales fueron comparadas con las demandas sísmicas según las provisiones de diseño de la norma peruana sísmica E.030 y un promedio de espectros de registros de aceleraciones de eventos sísmicos severos en Perú y escalados en un rango de 0.2T a 1.5T.
Finalmente, se determinó los puntos de desempeño para cada caso de edificación siguiendo las metodologías del ATC-40 encontrando que los edificios altos con núcleo rígido presentan aproximadamente el doble de rigidez que los edificios con sistema de disipación de energía, como también, presentan poca ductilidad a diferencia con los edificios con disipadores que presentan una larga ductilidad. / Currently in Lima city there is a limited number of high-rise buildings. So, there isn’t much literature on this type of building in Peru. Peruvian codes focus on medium and low-rise buildings. Therefore, more detailed studies are required to analyze and design these tall buildings more appropriately according to the reality of the country. In this thesis, the modal pushover analysis of 6 types of 35-story reinforced concrete buildings in Lima city will be developed.
Three building models with different structural system and with different plan (square and rectangular) are proposed, being their areas of 29m x 29m and 52m x 26m respectively. These structural systems are rigid core and frames with an energy dissipation system (viscous fluid dampers and SLB dissipators) in order to study their behavior against seismic stresses. These buildings were established based on the criteria and requirements of the current codes in the country, as well as, the distribution of the floors of buildings commonly used for offices and homes.
Natural periods were found to range from 2.6 to 3.3 seconds for rigid core buildings, there is an increase for viscous damping buildings from 4.2 to 5.4 seconds and also for SLB devices to range from 3.7 to 4.6 seconds. In turn, a modal static nonlinear analysis was performed to obtain the capacity curves for each type of building, which were compared with the seismic demands according to the design provisions of the Peruvian seismic code E.030 and an average of spectra of acceleration records of severe seismic events in Peru and scaled in a range of 0.2T to 1.5T.
Finally, the performance points for each building case were determined following the ATC-40 methodologies, finding that tall buildings with a rigid core have approximately twice the stiffness of buildings with an energy dissipation system, as well as having low ductility. unlike buildings with dissipators that have long ductility. / Tesis
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