Abstract
Previous studies demonstrated that the use of thermal mass in buildings can contribute to reduce the energy demand and improve the thermal comfort. The thermal mass effect strongly depends on the properties of the materials facing the internal environment. High thermal capacity and conductivity are vital to achieve the desired effects. Concrete have both and it is a common building material. However, scientifically sound experimental studies that quantify the effects in a controlled environment are scarce. The aim is to study the effects of thermal mass on indoor environment and comfort in a quantifiable way in an extensive experimental campaign where comparative measurements were carried out in The ZEB TestCell Laboratory in Trondheim, Norway. The facility consists of two identical real-weather exposed rooms the size of a single person office. One of the rooms was constructed with a 70 mm thick concrete flooring, the other with an 18 mm wood-flooring. Free-floating temperature propagations were measured in different natural ventilation scenarios. The results showed that peak temperatures were notably reduced in the test room with the concrete flooring. During the warmest periods, a temperature peak reduction of more than 10% was found compared to the wooden-floored room.
Highlights
In order to fulfil the goals of the Paris agreement, buildings of the future will be met by stricter and stricter demands for energy reductions
This paper presents the results of the first phase of an extensive experimental campaign aimed at quantification of the effects of a thermal mass on the internal thermal conditions of a single person office cubicles
This suggest that a substantial part of the thermal mass of the concrete tiles directly affected by solar radiation have been activated
Summary
In order to fulfil the goals of the Paris agreement, buildings of the future will be met by stricter and stricter demands for energy reductions. The effect of thermal mass on the behaviour of a building is a complex phenomenon being dependent on the material-related properties, climatic conditions and the resulting heat gains, losses and storage in the building materials and finishing. This phenomenon have been studies extensively [4], the number of experimental campaigns aimed at describing these phenomena using comparative monitoring campaigns are scarce [5]. Further studies are planned on investigating the effects on the energy demand for maintaining a comfortable thermal climate in the test cells
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