Characterization of soft ground wave amplifications in Cuenca.

Main Article Content

Marcelo Espinoza Cárdenas
Pablo Quinde Martínez

Abstract

Introduction. The problem caused by soft soils within the city of Cuenca, is increasingly increased due to the population expansion of the city, especially in two peripheral areas: Challuabamba and Nulti, presenting cases of slope instability, serious cracks in masonry, sinkholes etc. Target. In this article, an analysis is made of how seismic waves are amplified or attenuated in soft soils and allow us to determine the highest peak of frequencies and therefore calculate the fundamental period of the soil. Methodology. To determine the seismic records, it was done through geophysical tests of Seismic Refraction using the MASW method, six seismic lines were laid, two in Challuabamba and four in Nulti, which allowed us to determine the compression wave velocities (Vp), shear (Vs), and various elastic parameters of the soils studied. Results. With the elastic parameters calculated, and through the DEGTRA program, a mathematical modeling was carried out, using the Theoretical Transfer Functions, the result was the determination of the maximum frequency of the soil and in turn the period of the same, and make a comparison with the fundamental period calculated by seismic refraction. Conclusion. Through the Transfer Functions we can model how seismic waves are amplified or attenuated when transmitted within a soil stratum when perceiving a telluric movement, which are present day by day in our daily lives and especially in areas with a high seismic hazard., where site effects are the shapers of wave amplifications in soft soils.

Downloads

Download data is not yet available.

Article Details

How to Cite
Espinoza Cárdenas, M., & Quinde Martínez, P. (2022). Characterization of soft ground wave amplifications in Cuenca. ConcienciaDigital, 5(1), 188-207. https://doi.org/10.33262/concienciadigital.v5i1.2067
Section
Artículos

References

Álvarez-Icaza, Luis. (2014). Identificación de Rigidez En Los Entrepisos de Un Edificios Mediante Tiempos de Viaje de Onda. Congreso Nacional de Control Automático.
Ampuero, Alejandro. & Van Sint, M. (2004). “Velocidades de Onda Medidas En Santiago Con El Ensayo de Refracción Sísmica.” Geophysical Journal International, Doi: 182, 1, 355-367.
Bermeo Moyano, H. V. (2017). Determinación de Espectros de Respuesta y Espectros de Diseño Elásticos e Inelásticos Para La Ciudad de Cuenca.
Chávez, L. L. (2014). Efectos de Sitio Para Ingenieros Geotécnicos, Estudio Del Valle Parkway. Obras y Proyectos (16):6–30.
Ilori, A. O. (2019). Extracting Some soil parameters and estimating elastic settlements from direct shear box data for a granular c-empty set soil. SN APPLIED SCIENCES 1(10). Doi: 10.1007/s42452-019-1347-x.
Jiménez, J., Cabrera, J., Sánchez, J. & Avilas, A. (2018). Vulnerabilidad sísmica del patrimonio edificado del Centro Histórico de la Ciudad de Cuenca: Lineamientos generales y avances del proyecto. MSKN MASKANA 9(1):59-78. ISSN: 1390-6143.doi.org/10.18537/mskn.09.01.0. Doi: doi.org/10.18537/mskn.09.01.07.
Mohammed, M. A., Abudeif, A. M. & Abd, A. K. (2020). Engineering Geotechnical Evaluation of Soil for Foundation Purposes Using Shallow Seismic Refraction and MASW in 15th Mayo, Egypt. Journal of African Earth Sciences 162. Doi: 10.1016/j.jafrearsci.2019.103721.
Negreros, Ramiro. & Gonzales, Alfonso. (2018). Universidad de San Carlos de Guatemala Facultad de Ingeniería Escuela de Ingeniería Civil.
Pickering, D. J. (1970). Anisotropic Elastic Parameters for Soil. Geotechnique 20(3):271–76. Doi: 10.1680/geot.1970.20.3.271.
Taipe Acosta, L. M. (2013). Análisis de las ecuaciones de predicción de movimientos de suelo para el ecuador utilizando datos registrados durante el periodo 2000-2011 en las estaciones, sísmicas de banda ancha y acelerógrafos. Http://Bibdigital.Epn.Edu.Ec/Handle/15000/6447
Vanegas Camero, M. J. (2020). Modelación Experimental y Analítica Del Comportamiento Dinámico de Un Suelo Blando.