Abstract
Energy-efficient building design needs an accurate way to estimate temperature inside the building which facilitates the calculation of heating and cooling energy requirements in order to achieve appropriate thermal comfort for occupants. Sky temperature is an important factor for any building assessment tool which needs to be precisely determined for accurate estimation of the energy requirement. Many building simulation tools have been used to calculate building thermal performance such as Autodesk Computational Fluid Dynamics (CFD) software, which can be used to calculate building internal air temperature but requires sky temperature as a key input factor for the simulation. Real data obtained from real-sized house modules located at University of Newcastle, Australia (southern hemisphere), were used to find the impact of different sky temperatures on the building’s thermal performance using CFD simulation. Various sky temperatures were considered to determine the accurate response which aligns with a real trend of buildings’ internal air temperature. It was found that the internal air temperature in a building keeps either rising or decreasing if higher or lower sky temperature is chosen. This significantly decreases the accuracy of the simulation. It was found that using the right sky temperature values for each module, Cavity Brick Module (CB) Insulated Cavity Brick Module (InsCB), Insulated Brick Veneer Module (InsBV) and Insulated Reverse Brick Veneer Module (InsRBV), will result in 6.5%, 7.1%, 6.2% and 6.4% error correspondingly compared with the real data. These errors mainly refer to the simulation error. On the other hand using higher sky temperatures by +10 °C will significantly increase the simulation error to 16.5%, 17.5%, 17.1% and 16.8% and lower sky temperature by +10 °C will also increase the error to 19.3%, 22.6%, 21.9% and 19.1% for CB, InsCB, InsBV and InsRBV modules, respectively.
Highlights
The building sector contributes to climate change where energy usage in constructing and operating buildings account for 40% of the global energy use [1] and 32% of greenhouse gas (GHG)emissions [2]
An accurate sky temperature used in Computational Fluid Dynamics (CFD) simulations or another buildings energy assessment program (e.g., EnergyPlus) is necessary to reflect the real performance of the buildings
This may lead to incorrect assessment of the existing or new buildings’ thermal performance, operating energy, and GHG emission over the entire life-span
Summary
The building sector contributes to climate change where energy usage in constructing and operating buildings account for 40% of the global energy use [1] and 32% of greenhouse gas (GHG)emissions [2]. The building sector contributes to climate change where energy usage in constructing and operating buildings account for 40% of the global energy use [1] and 32% of greenhouse gas (GHG). Ways to decrease GHG emissions and save energy play an important role in designing energy-efficient structures. The increasing demands for energy, climate change, and the imperative to reduce greenhouse gas emissions must be considered in designing buildings. Energy-efficient buildings are vital as they reduce the consumption of energy and allow sustainable development. Erecting such buildings will require correct and realistic prediction of the buildings’ performance when subjected to a wide variety of harsh weather conditions in order
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