Abstract
Existing regulations on the thermal efficiency of building envelope assemblies are based on the steady state thermal properties of substrate materials. Heat transfer mechanisms of passive heat curbing methods such as phase change materials and cool materials, which are dynamic in nature, are currently not being accounted for. The effectiveness of thermo-physical and solar radiation properties of building materials (i.e., solid homogeneous layers without air gap) in reducing the heat gain into a building in a hot climate could be well understood with the equivalent thermal resistance (Req) concept. A simple and easy-to-use mathematical derivation (i.e., to estimate the instantaneous heat flux across an envelope assembly) is proposed in this paper to understand the mechanism of equivalent R-value (i.e., reciprocal of thermal transmittance, U-value) due to solar radiation properties of passive substrate materials. The model is validated against field experiments carried out at two apartment units of a residential building. The Req due to high outer surface solar radiation properties (i.e., by applying a cool coating) is dynamic as it varies with the weather conditions. The effect of a substrate material’s solar radiation and thermo-physical properties on the overall roof thermal performance is investigated using the Req model for four cooling dominated climates around the globe, having different diurnal conditions and sky temperatures. Increasing the outer surface’s solar reflectance (from 10% to 80%) reduces net heat gain through the flat roof during both daytime and nighttime. In contrast, adding only thermal resistance (from 5 mm to 75 mm thick polyurethane) or volumetric heat capacity (by adding 5 mm thick phase change material) to the building envelope brings down heat gain during the day, but not in the night. Thermal insulation is found to be the second effective property, followed by thermal mass irrespective of different diurnal conditions and sky temperatures across the climates.
Highlights
Solar irradiation incidents on an opaque envelope assembly are partially reflected and the remaining are absorbed at the outdoor exposed surface
This section elaborates the impact of cool coating along with that of thermal resistance and volumetric heat capacity of the substrate material using the proposed heat transfer model
Under different climate conditions by (i) applying cool coating, (ii) topping up the insulation layer and (iii) adding thermal mass
Summary
Solar irradiation incidents on an opaque envelope (roof and walls) assembly are partially reflected and the remaining are absorbed at the outdoor exposed surface. Energies 2020, 13, 5119 to curb the inward heat transfer by conduction, (iii) adding thermal mass to enhance the storage of generated heat (during the daytime) in the outdoor exposed surface and later releasing it back to the outdoor environment (during the nighttime). These three strategies could be achieved, e.g., (i) by applying a cool coating/material on the outdoor exposed envelope surface [1,2], (ii) by topping up a layer of insulation [3], or (iii) by adding heavy construction materials or phase-change materials [4,5,6,7,8].
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