Evolución de la modelización numérica bidimensional del flujo en lámina libre a través del software Iber

Proyecto “DRAIN - Digital RAIN. Un modelo integrado de drenaje urbano” (CPP2021-008756) financiado por el Ministerio de Ciencia, Innovación y Universidades/Agencia Estatal de Investigación/10.13039/501100011033/

Plan de Recuperación, Transformación y Resiliencia de España: Next Generation EU/PRTR de la Unión Europea

Resumen:

Iber es una herramienta de simulación hidráulica bidimensional surgida desde la academia para dar solución a problemas de ingeniería hidráulica y ambiental. Desde su nacimiento en 2010 se ha convertido en un software ampliamente aceptado para simular procesos hidrodinámicos de flujo en lámina libre. Este trabajo presenta la evolución de Iber y analiza las mejoras llevadas a cabo que actualmente permiten realizar simulaciones, completamente acopladas con la hidrodinámica, de transporte de sedimentos y calidad de aguas, de procesos hidrológicos a nivel de cuenca rural y urbana, de eco-hidráulica, etc. Los módulos y capacidades de cálculo implementados, así como las líneas de trabajo futuras, demuestran que la modelización hidrodinámica bidimensional todavía tiene un gran margen para el desarrollo de nuevas aplicaciones y mejoras. Iber sigue unas líneas de desarrollo con un enfoque eminentemente práctico, permitiendo a usuarios y usuarias realizar simulaciones cada vez más fidedignas al proceso físico a representar.

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Sanz-Ramos, M., López-Gómez, D., Bladé, E., Dehghan-Souraki, D. 2023a. A CUDA Fortran GPU-parallelised hydrodynamic tool for high-resolution and long-term eco-hydraulic modelling. Environ. Model. Softw., 161, 105628, https://doi.org/10.1016/j.envsoft.2023.105628

Sanz-Ramos, M., Bladé, E., Silva-Cancino, N., Salazar, F., López-Gómez, D., Martínez-Gomariz, E. 2023b. A Probabilistic Approach for Off-Stream Reservoir Failure Flood Hazard Assessment. Water, 15, 2202, https://doi.org/10.3390/w15122202

Sanz-Ramos, M., Bladé, E., Sánchez-Juny, M. 2023c. El rol de los términos de fricción y cohesión en la modelización bidimensional de fluidos no Newtonianos: avalanchas de nieve densa. Ingeniería del Agua, 27, 295–310, https://doi.org/10.4995/ia.2023.20080

Sanz-Ramos, M., Bladé, E., Oller, P., Furdada, G. 2023d. Numerical modelling of dense snow avalanches with a well-balanced scheme based on the 2D shallow water equations. J. Glaciol., 69(278) 1–17, https://doi.org/10.1017/jog.2023.48

Sanz-Ramos, M., Bladé, E., Silva-Cancino, N., Salazar, F. 2024a. Avances en Iber para la clasificación de balsas: proyecto ACROPOLIS. Ingeniería del Agua, 28, 47–63, https://doi.org/10.4995/ia.2024.20609

Sanz-Ramos, M., Bladé, E., Sánchez-Juny, M., Dysarz, T. 2024b. Extension of Iber for Simulating Non–Newtonian Shallow Flows: Mine-Tailings Spill Propagation Modelling. Water, 16, 2039, https://doi.org/10.3390/w16142039

Sanz-Ramos, M., Vales-Bravo, J.J., Bladé, E., Sánchez-Juny, M. 2024c. Reconstructing the spill propagation of the Aznalcóllar mine disaster. Mine Water Environ., 43, https://doi.org/10.1007/s10230-024-01000-5

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Evolución de la modelización numérica bidimensional del flujo en lámina libre a través del software Iber

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