Abstract
Systematic studies of the thermal fluid dynamic behaviour of building envelope systems through experiment analyses is limited by the relevant amount of time and high costs necessary to carry out a relevant number of tests covering all the possible configurations. Building simulation can be used as a tool to support the design of the experiments, i.e. to test, in a parametric way, different configurations to highlight the main trends, and therefore select the most relevant cases to be tested experimentally. Such a preliminary activity to maximize the effectiveness of the experiments may relates to both parametric analysis of indoor/outdoor boundary conditions, as well as parametric analysis of building envelope configurations. In the framework of a research project on double skin facade (DSF) systems where experiments are planned on a full-scale prototype, a model of a DSF is realized in a whole building energy software tool, and used to carry out a preliminary sensitivity analysis, by means of orthogonal array method and analysis of variance. Simulations were carried out in EnergyPlus, using the Airflow window module, and under steady-state conditions, a series of variables (cavity depth, venetian blinds tilt angle, airflow rate) have been investigated to assess their impact on the heat extract through the ventilation air and the total heat transmission between the outdoor and indoor environment. The results show that the main driver in the performance of DSF considering net heat rate transfer is the irradiation impinging on the façade in terms of boundary conditions, and coherently, the shading device is the feature that most affects the performance of the system among the characteristics of a DSF.
Highlights
Double skin facade (DSF) systems have become an interesting and important architectural element in buildings in the last few decades because of their transparency look and potentials for reduction of energy demand compared to conventional, single skin facades [1]
In the framework of a research project on double skin facade (DSF) systems where experiments are planned on a full-scale prototype, a model of a DSF is realized in a whole building energy software tool, and used to carry out a preliminary sensitivity analysis, by means of orthogonal array method and analysis of variance
The results show that the main driver in the performance of DSF considering net heat rate transfer is the irradiation impinging on the façade in terms of boundary conditions, and coherently, the shading device is the feature that most affects the performance of the system among the characteristics of a DSF
Summary
Double skin facade (DSF) systems have become an interesting and important architectural element in buildings in the last few decades because of their transparency look and potentials for reduction of energy demand compared to conventional, single skin facades [1]. To really achieve a good energy performance, double skin facades need to be properly designed, and because of their intrinsic complexity, such a task is not trivial This means that a designer needs to rely on numerical tools that can replicate the fluid mechanic and thermal phenomena occurring in the DSF and, that such physical processes are well understood - as well as properly modelled in simulation tools. Experimental analyses are aimed at both assessing the energy performance and investigating the complex interrelation of thermophysical phenomena occurring in the systems (thermophysical behaviour of DSFs in relation to cavity features, shadings, and airflows). These activities will be based on tests carried out on a full-scale prototype/testbed, installed in a climate simulator located in the laboratories of NTNU and SINTEF
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