Your search keyword '"Eben, Kryštof"' showing total 2 results

1. Validation of the PALM model system 6.0 in a real urban environment: A case study in Dejvice, Prague, the Czech Republic

Author

Resler, Jaroslav, Eben, Kryštof, Geletič, Jan, Krč, Pavel, Rosecký, Martin, Sühring, Matthias, Belda, Michal, Fuka, Vladimír, Halenka, Tomáš, Huszár, Peter, Karlický, Jan, Benešová, Nina, Ďoubalová, Jana, Honzáková, Kateřina, Keder, Josef, Nápravníková, Šárka, Vlček, Ondřej, Resler, Jaroslav, Eben, Kryštof, Geletič, Jan, Krč, Pavel, Rosecký, Martin, Sühring, Matthias, Belda, Michal, Fuka, Vladimír, Halenka, Tomáš, Huszár, Peter, Karlický, Jan, Benešová, Nina, Ďoubalová, Jana, Honzáková, Kateřina, Keder, Josef, Nápravníková, Šárka, and Vlček, Ondřej

Abstract

In recent years, the PALM 6.0 modelling system has been rapidly developing its capability to simulate physical processes within urban environments. Some examples in this regard are energy-balance solvers for building and land surfaces, a radiative transfer model to account for multiple reflections and shading, a plant-canopy model to consider the effects of plants on flow (thermo)dynamics, and a chemistry transport model to enable simulation of air quality. This study provides a thorough evaluation of modelled meteorological, air chemistry, and ground and wall-surface quantities against dedicated in situ measurements taken in an urban environment in Dejvice, Prague, the Czech Republic. Measurements included monitoring of air quality and meteorology in street canyons, surface temperature scanning with infrared cameras, and monitoring of wall heat fluxes. Large-eddy simulations (LES) using the PALM model driven by boundary conditions obtained from a mesoscale model were performed for multiple days within two summer and three winter episodes characterized by different atmospheric conditions. For the simulated episodes, the resulting temperature, wind speed, and chemical compound concentrations within street canyons show a realistic representation of the observed state, except that the LES did not adequately capture night-Time cooling near the surface for certain meteorological conditions. In some situations, insufficient turbulent mixing was modelled, resulting in higher near-surface concentrations. At most of the evaluation points, the simulated surface temperature reproduces the observed surface temperature reasonably well for both absolute and daily amplitude values. However, especially for the winter episodes and for modern buildings with multilayer walls, the heat transfer through walls is not well captured in some cases, leading to discrepancies between the modelled and observed wall-surface temperature. Furthermore, the study corroborates model dependency on the

Published

2021

2. Sensitivity analysis of the PALM model system 6.0 in the urban environment

Author

Belda, Michal, Resler, Jaroslav, Geletič, Jan, Krč, Pavel, Maronga, Björn, Sühring, Matthias, Kurppa, Mona, Kanani-Sühring, Farah, Fuka, Vladimír, Eben, Kryštof, Benešová, Nina, Auvinen, Mikko, Belda, Michal, Resler, Jaroslav, Geletič, Jan, Krč, Pavel, Maronga, Björn, Sühring, Matthias, Kurppa, Mona, Kanani-Sühring, Farah, Fuka, Vladimír, Eben, Kryštof, Benešová, Nina, and Auvinen, Mikko

Abstract

Sensitivity of the PALM model 6.0 with respect to land-surface and building properties is tested in a real urban environment in the vicinity of a typical crossroads in a densely built-up residential area in Prague, Czech Republic. The turbulence-resolving PALM is able to simulate the urban boundary layer flow for realistic setups. Besides an accurate representation of the relevant physical processes, the model performance also depends on the input data describing the urban setup, namely the building and land-surface properties. Two types of scenario are employed. The first one is the synthetic scenarios altering mainly surface and material parameters such as albedo, emissivity or wall conductivity, testing sensitivity of the model simulations to potentially erroneous input data. Second, urbanistic-type scenarios are analysed, in which commonly considered urban heat island mitigation measures such as greening of the streets or changing surface materials are applied in order to assess the limits of the effects of a particular type of scenario. For the synthetic scenarios, surface parameters used in radiation balance equations are found to be the most sensitive overall followed by the volumetric heat capacity and thermal conductivity of walls. Other parameters show a limited average effect; however, some can still be significant during some parts of the day, such as surface roughness in the morning hours. The second type, the urbanistic scenarios, shows urban vegetation to be the most effective measure, especially when considering both physical and biophysical temperature indicators. The influence of both types of scenario was also tested for air quality, specifically PM2.5 dispersion, which generally shows opposite behaviour to that of thermal indicators; i.e. improved thermal comfort brings deterioration of PM2.5 concentrations. © 2021 Michal Belda et al.

Published

2021