Validation of an immersed boundary framework for urban flows
Paper in proceeding, 2022

Urban heat islands, or the phenomena of locally increased temperatures of urban areas compared to their rural surroundings, are becoming increasingly problematic with global warming and the rise of urbanization. Therefore, new areas must be planned considering appropriate ventilation to mitigate these high-temperature regions and cooling strategies, such as green infrastructures, must be considered. Typically, these critical environmental issues are assessed in the final stages of urban planning when further strategic interventions are no longer possible. Here, a numerical framework is tested, that urban planners can use as a future tool to analyze complex fluid dynamics and heat transfer in the early stages of urban planning. The framework solves the RANS equations using an immersed boundary approach to discretize the complex urban topography in a cartesian octree grid. The grid is automatically generated, eliminating the complex pre-processing of urban topographies and making the framework accessible for all users. The results are validated against experimental data from wind tunnel measurements of wind-driven ventilation in street canyons. This work present similarities and differences between experiments and simulations using three different turbulence models. Finally, guidelines will be provided on the choice of minimum grid sizes required to capture the relevant flow structures inside a canyon accurately.

Ventilation

Urban climate

Immersed Boundary

Street Canyons

Author

Patricia Vanky

Chalmers, Mechanics and Maritime Sciences (M2), Fluid Dynamics

Andreas Mark

Marie Haeger-Eugensson

Joaquim Tarraso

Chalmers, Architecture and Civil Engineering, Urban Design and Planning

Marco Adelfio

Chalmers, Architecture and Civil Engineering, Urban Design and Planning

Angela Sasic Kalagasidis

Chalmers, Architecture and Civil Engineering, Building Technology

Gaetano Sardina

Chalmers, Mechanics and Maritime Sciences (M2), Fluid Dynamics

Proceedings of the Conference on Modelling Fluid Flow CMFF’22

Vol. 18 237-245 044
978-963-421-881-4 (ISBN)

Conference on Modelling Fluid Flow 2022
Budapest, Hungary,

UEQ - simulations, visualizations and evaluations of future sustainable urban environments

Formas (2019-01885), 2020-01-01 -- 2023-12-31.

Driving Forces

Sustainable development

Subject Categories

Environmental Analysis and Construction Information Technology

Other Civil Engineering

Fluid Mechanics and Acoustics

More information

Latest update

10/26/2023