Exploring the Interplay between CAD and FreeFem++ as an Energy Decision-Making Tool for Architectural Design

Rojas-Fernández, Juan Manuel; Galán-Marín, Carmen; Rivera-Gómez, Carlos; Fernández-Nieto, Enrique D.

doi:10.3390/en11102665

Cited by 7 publications

(8 citation statements)

References 22 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Although there are many simulation tools to predict the energy performance of buildings, the complex thermodynamic effects that happen in courtyards require simulation tools with high computational resources and thousands of simulation hours to calculate and simulate a representative period, based on CFD (Computational Fluid Dynamics) and finite elements (Blocken et al 2011). In the analysis performed by Rojas et al (Rojas-Fernández et al 2018), the main available simulation tools are analysed concerning their capacity to simulate transitional spaces from the point of view of a professional of the building sector. They found that there is no available software that meets all requirements for this reliable microclimate simulation.…”

Section: Introductionmentioning

confidence: 99%

Modelling of surface and inner wall temperatures in the analysis of courtyard thermal performances in Mediterranean climates

López-Cabeza

Carmona-Molero

Rubino

et al. 2021

Journal of Building Performance Simulation

View full text Add to dashboard Cite

Courtyards are an effective passive strategy for improving the energy performance of buildings. However, there is a lack of accurate simulation tools for their thermal performance due to their complex thermodynamics. This paper's contribution is the coupling of a CFD model with a system of differential equations at the walls, governing surface and inner wall temperatures, providing an accurate computation of courtyard thermal performance. On this basis, boundary conditions for the standard Boussinesq equations governing temperatures, wind velocity, and pressure within the courtyard are established. Modelling results are compared with monitored data in two days of different months in a courtyard in Seville (Spain). Simultaneously, simulations carried out by existing software were performed. Resulting data showed more accuracy than existing tools, with a Root Mean Square Error of 1.19 (August) and 1.59 (October), while the corresponding values with ENVI-met were 3.31-3.4, and with Ladybug Tools 2.59-4.49.

show abstract

Section: Introductionmentioning

confidence: 99%

Modelling of surface and inner wall temperatures in the analysis of courtyard thermal performances in Mediterranean climates

López-Cabeza

Carmona-Molero

Rubino

et al. 2021

Journal of Building Performance Simulation

View full text Add to dashboard Cite

show abstract

“…The courtyard microclimate can be explained in terms of the thermodynamic effects that occur within it, i.e., convection, radiation, stratification, and flow patterns. Among the different parameters affecting these microclimatic conditions, most of the studies emphasize the importance of courtyard geometry [13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29], in many cases considered the Aspect Ratio (AR), which is the ratio between the height and the width of the courtyard.…”

Section: Introductionmentioning

confidence: 99%

“…Courtyard location, implying climatic conditions and specifically outdoor temperature ranges, is another key factor that is becoming commonplace in a large number of publications [14][15][16][17][18][19][20][21][25][26][27][28][29][30].…”

Section: Introductionmentioning

confidence: 99%

“…One of the most widely used tools is ENVI-met, based on CFD simulation [32]. Other outdoor modeling software alternatives are Urban Weather Generator (UWG), based on energy conservation principles [33]; SOLWEIG, which can simulate spatial variations of 3D radiation fluxes and mean radiant temperatures [34]; Open FOAM, which has been used in previous research to simulate urban wind flows [35]; FreeFem++, employed to perform courtyard microclimate modelling [17,36]; and ANSYS Fluent, which has been applied for the simulation of wind flows in outdoor spaces [17,36]. Most of these tools present adequate accuracy for predicting urban outdoor microclimates, but they tend to show a larger error range when they are used to model the microclimate of smaller-scale spaces, such as courtyards, with greater dependence on the built environment [12,36].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Applied Machine Learning Algorithms for Courtyards Thermal Patterns Accurate Prediction

et al. 2021

Self Cite

View full text Add to dashboard Cite

Currently, there is a lack of accurate simulation tools for the thermal performance modeling of courtyards due to their intricate thermodynamics. Machine Learning (ML) models have previously been used to predict and evaluate the structural performance of buildings as a means of solving complex mathematical problems. Nevertheless, the microclimatic conditions of the building surroundings have not been as thoroughly addressed by these methodologies. To this end, in this paper, the adaptation of ML techniques as a more comprehensive methodology to fill this research gap, covering not only the prediction of the courtyard microclimate but also the interpretation of experimental data and pattern recognition, is proposed. Accordingly, based on the climate zoning and aspect ratios of 32 monitored case studies located in the South of Spain, the Support Vector Regression (SVR) method was applied to predict the measured temperature inside the courtyard. The results provided by this strategy showed good accuracy when compared to monitored data. In particular, for two representative case studies, if the daytime slot with the highest urban overheating is considered, the relative error is almost below 0.05%. Additionally, values for statistical parameters are in good agreement with other studies in the literature, which use more computationally expensive CFD models and show more accuracy than existing commercial tools.

show abstract

“…In contrast to the tools that consider the optimisation of energy systems with detailed building models [13,20], this article focuses on the tools that make a compromise between the accurate calculations of the physical properties of one building, and the optimisation of these properties for multiple buildings and the components of their energy systems. Such tools that can optimise the energy system for a settlement or urban quarter are already available (e.g., RETScreen [21] and the tools developed by the passive house institute).…”

Section: Introductionmentioning

confidence: 99%

Linear Optimisation of a Settlement Towards the Energy-Plus House Standard

Slonski¹,

Schrag²

2019

Energies

View full text Add to dashboard Cite

Future buildings will use technologies that are either well-known, innovative, or a combination thereof in order to be environmentally friendly and feasible at the same time. To evaluate and compare such systems through simulation, adaptive tools need to be available. This paper describes a conceived method for planning quarters and settlements. The novelty of this work emerges from the combination of a building simulation with a linear economic optimisation of the energy system, to achieve the energy-plus house standard for a settlement. Furthermore, the tools applied are adaptive or open source. In this article, a hypothetical basic example is given for a predefined idealised settlement, which consists of 132 single-family houses of one building type. The hourly demand for electrical energy and heat is established for three energy-efficiency classes for the building type with a dynamic simulation in MATLAB/SIMULINK using the CARNOT toolbox. This toolbox is also used to calculate the specific electrical energy production by photovoltaics. The components for the energy system of the settlement are implemented in the open source linear optimisation tool URBS. An economic optimum for the energy system of the settlement is found for each of the energy efficiency classes for an accumulated energy demand of the buildings. In this way, a lossless energy hub between the buildings is assumed. The results of the conducted simulations indicate that the optimal ratio of air/water to ground/water heat pumps shifts towards air/water heat pumps with more energy efficient houses. This is due to the lower specific investment costs, which outweigh the operational costs when less energy is required. The lowest costs for the entire energy system are for the one with the most energy efficient settlement. This is the case, as the costs for the higher energy standard of the buildings are not considered in the calculations. The behaviour of the optimisation is tested and discussed through a sensitivity analysis for one efficiency class. By presenting this simple, comprehensible example, an impression of the possible applications for this methodology is conveyed.

show abstract

Exploring the Interplay between CAD and FreeFem++ as an Energy Decision-Making Tool for Architectural Design

Cited by 7 publications

References 22 publications

Modelling of surface and inner wall temperatures in the analysis of courtyard thermal performances in Mediterranean climates

Modelling of surface and inner wall temperatures in the analysis of courtyard thermal performances in Mediterranean climates

Applied Machine Learning Algorithms for Courtyards Thermal Patterns Accurate Prediction

Linear Optimisation of a Settlement Towards the Energy-Plus House Standard

Contact Info

Product

Resources

About