Development and validation of a Monte Carlo-based numerical model for solar analyses in urban canyon configurations

Development and validation of a Monte Carlo-based numerical model for solar analyses in urban canyon configurations

Highly- and retro-reflective materials have recently been investigated and proposed as a new urban coating solution to reduce the so-called urban heat island effect. The present study aims at providing a numerical model for assessing inter-buildings solar reflections when these materials are applied...

Full description

Saved in:
Bibliographic Details
Published in:Building and environment Vol. 170; p. 106638
Main Authors: Manni, Mattia, Bonamente, Emanuele, Lobaccaro, Gabriele, Goia, Francesco, Nicolini, Andrea, Bozonnet, Emmanuel, Rossi, Federico
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-03-2020
Elsevier
Subjects:
2D urban canyon
Cool materials
Engineering Sciences
Full ray-tracing assessment
Monte Carlo method
Solar analyses
Cool materials
Monte Carlo method
Solar analyses
Full ray-tracing assessment
2D urban canyon
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Highly- and retro-reflective materials have recently been investigated and proposed as a new urban coating solution to reduce the so-called urban heat island effect. The present study aims at providing a numerical model for assessing inter-buildings solar reflections when these materials are applied to urban canyon's surfaces. The proposed model includes a function that accounts for sunray angle dependency of the solar reflectance, which is specifically important with regard to retro-reflective behavior. The novelty of this numerical model based on a Monte Carlo simulation approach implemented in the Matlab simulation environment is to conduct full ray-tracing solar analyses which can reproduce the energy exchange phenomena and simulate optical material properties. Experimental validation and inter-software comparison are carried out with measured data collected in an experimental facility in La Rochelle, France, in addition to simulation results from the Radiance-based Diva for Rhino tool. The results of the numerical model developed are in line with the values measured in the physical model (daily percent variation of 1.3% in summer) and within the boundary conditions defined in the present work. The residues, which were calculated for the hourly values throughout the day, are found to be in the range of ± 10 W/m2, with the arithmetic average and standard deviation equal to – 2 W/m2 and 7 W/m2 respectively. •A Monte Carlo-based model for full ray-tracing solar analyses is developed.•The numerical model contributes to the development of retro-reflective technology.•The numerical model is validated against experimental data from La Rochelle, France.•An inter-software comparison is conducted between the model and Diva for Rhino.•Simulation outputs from the numerical model are in line with those from Diva for Rhino.
ISSN:0360-1323
1873-684X
DOI:10.1016/j.buildenv.2019.106638