Breathing Walls are envelope components, based on porous materials, crossed by a natural or forced airflow. Since they behave both as recovery heat exchangers and active insulation, reducing the conductive heat flux, they represent a promising envelope technology, allowing to reduce energy consumption in buildings.From the modeling point of view, an analytical model can be found in literature, describing heat and mass transfer across Breathing Walls in steady state conditions. However, to the best of the authors' knowledge, the model lacks an exhaustive experimental validation. Therefore, in this paper, the novel laboratory apparatus named Dual Air Vented Thermal Box developed at Politecnico of Milano is presented. The apparatus is used to experimentally investigate the steady state behavior of a 1 m 2 Air Permeable Concrete sample, crossed by an airflow at different velocities up to 12 mm/s.The temperature profile inside the sample, measured in different positions, is compared with the model predictions. While in the central portion of the wall a very good agreement is found, the experimental results at the top and at the bottom of the wall suggest a non-uniform velocity field entering the sample. A qualitative confirmation of this hypothesis is provided by CFD simulations on the apparatus, clearly showing a mixed convection regime on both sides of the wall. The results lead to state the validity of the one-dimensional analytical model in literature, although a careful application should take into account adjusted boundary conditions, consisting in an airflow velocity possibly variable with height.
The suitability of night ventilation to reduce the cooling demand in buildings can be evaluated by
coupling Airflow Network Models to Building Energy Simulation tools. To estimate wind-induced
ventilation, pressure coefficients (Cp) on the building envelope are key inputs, as well as local wind speed
and direction. Cp data obtained by primary sources such as measurements or CFD simulations are
considered the most reliable but can be difficult to obtain. An easy alternative are Cp secondary sources,
such as databases providing literature data correlations. Therefore an issue arises regarding the choice of
the source of pressure coefficients.
This paper investigates the effects of Cp from primary and secondary sources on the predicted energy
saving potential of night ventilation of an isolated office building for several European climates and some
relevant design conditions and simulation parameters. Different Cp sources produce a dispersion of Cp
data and differences in the calculated night ventilation rates up to 15%. Contrary to what might be
expected, these differences influence only marginally the resulting passive cooling effects. Overall a
stronger impact is observed for the colder climates, where higher temperature differences occur between
desired indoor temperature and night-averaged outdoor temperature. Finally, for the building under
study, the choice of the Cp source appears less crucial than the choice of other building simulation
parameters, such as the internal Convective Heat Transfer Coefficient. This study can support building
designers towards accurate energy simulations of naturally ventilated buildings
U-pipes for ground source heat pump (GSHP) installations are generally inserted in vertical boreholes back-filled with pumpable grouts. Grout thermal conductivity is a crucial parameter, dominating the borehole thermal resistance and impacting the heat exchanger efficiency. In order to seal the borehole and prevent leakages of the heat carrier fluid, grouting materials are also hydraulically impermeable, so that groundwater flow inside the borehole is inhibited. The influence of groundwater flow on the borehole heat exchangers (BHE) performance has recently been highlighted by several authors. However groundwater impact and grouting materials influence are usually evaluated separately, disregarding any combined effect. Therefore simulation is used to investigate the role of the thermal and hydraulic conductivities of the grout when the BHE operates in an aquifer with a relevant groundwater flow. Here 3 main cases for a single U-pipe in a sandy aquifer are compared. In Case 1 the borehole is back-filled with the surrounding soil formation, while a thermally enhanced grout and a low thermal conductivity grout are considered in Case 2 and Case 3 respectively. Simulations are carried out maintaining the inlet temperature constant in order to reproduce the yearly operation of the GSHP system. For each of the 3 cases three different groundwater flow velocities are considered. The results show that a high thermal conductivity grout further enhances the effects of a significant groundwater flow. The conditions when neglecting the grout material in the numerical model does not lead to relevant errors are also identified.
Breathing Walls are air permeable envelope components based on porous materials. In contra-flux operation air flows opposite to \ud
conductive flux, while in pro-flux they have the same direction. The Breathing Wall behaves either as a ventilation heat exchanger \ud
or as an active insulation. \ud
In literature an analytical model describing steady state heat transfer across a Breathing Wall can be found. Since it lacks an \ud
exhaustive experimental validation, a facility developed at the Energy Department of Politecnico of Milano was used to investigate \ud
the thermo-physical behavior of a no-fines concrete based Breathing Wall in steady state Dirichlet conditions and contra-flux \ud
operation
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