Abstract
To design energy-efficient buildings, energy assessment programs need to be developed for determining the inside air temperature, so that thermal comfort of the occupant can be sustained. The internal temperatures could be calculated through computational fluid dynamics (CFD) analysis; however, miniscule time steps (seconds and milliseconds) are used by a long-term simulation (i.e., weeks, months) that require excessive time for computing wind effects results even for high-performance personal computers. This paper examines a new method, wherein the wind effect surrounding the buildings is integrated with the external air temperature to facilitate wind simulation in building analysis over long periods. This was done with the help of an equivalent temperature (known as Tnatural), where the convection heat loss is produced in an equal capacity by this air temperature and by the built-in wind effects. Subsequently, this new external air temperature Tnatural can be used to calculate the internal air temperature. Upon inclusion of wind effects, above 90% of the results were found to be within 0–3 °C of the perceived temperatures compared to the real data (99% for insulated cavity brick (InsCB), 91% for cavity brick (CB), 93% for insulated reverse brick veneer (InsRBV) and 94% for insulated brick veneer (InsBV) modules). However, a decline of 83–88% was observed in the results after ignoring the wind effects. Hence, the presence of wind effects holds greater importance in correct simulation of the thermal performance of the modules. Moreover, the simulation time will expectedly reduce to below 1% of the original simulation time.
Highlights
The building sector is responsible for a high level of greenhouse gas (GHG) emissions, because of its tremendous energy consumption
There are different software packages used in building thermal simulation [7], for example, the expertise of TRNSYS (Transient System Simulation Tool, developed at the University of Wisconsin, USA) can be utilized in complete solar energy system modeling, while application of computational fluid dynamics (CFD) can be observed in building design from building site layout design to individual room planning
If smaller time steps are used for wind, the long-term simulation would not be possible, which is the motivation behind the development of a new technique for accelerating the simulation by combining the wind effect with outside air temperature around the building
Summary
The building sector is responsible for a high level of greenhouse gas (GHG) emissions, because of its tremendous energy consumption. There are different software packages used in building thermal simulation [7], for example, the expertise of TRNSYS (Transient System Simulation Tool, developed at the University of Wisconsin, USA) can be utilized in complete solar energy system modeling, while application of CFD can be observed in building design from building site layout design to individual room planning. It can be used for active Heating and passive Ventilation study to ventilating and Air-Conditioning (HVAC) system design, and from serious fire, smoke, and toxin control to consistent indoor air quality valuation [8]. Computational fluid dynamics is employed as a state-of-the-art technique for modeling airflow and is effective at predicting airflow, heat transfer as well as the transportation of pollutants into and around structures
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