Properties of concretes enhanced with phase change materials for building applications

•Organic paraffins and non-paraffins are suitable PCMs for incorporation into concrete.•Indirect methods of PCM incorporation into concrete avoid PCM leakage.•Microcapsules could help reduce the loss in the compressive strength of PCM-concrete.•Testing specifications for measuring thermal properties...

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Bibliographic Details
Published in:Energy and buildings 2019-09, Vol.199, p.402-414
Main Authors: Berardi, Umberto, Gallardo, Andres Alejandro
Format: Article
Language:English
Subjects:
Building envelopes
Buildings
Concrete
Concrete construction
Construction materials
Electricity consumption
Encapsulation
Energy demand
Heat storage
HVAC equipment
Mechanical properties
Melting points
Organic chemistry
Paraffin
Paraffins
Passive thermal regulation
Peak load
Phase change materials
Storage capacity
Test procedures
Testing procedures
Thermal energy
Thermal energy storage
Thermal mass
Thermal properties
Thermal stability
Thermal storage
Thermodynamic properties
Vacuum
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Summary:•Organic paraffins and non-paraffins are suitable PCMs for incorporation into concrete.•Indirect methods of PCM incorporation into concrete avoid PCM leakage.•Microcapsules could help reduce the loss in the compressive strength of PCM-concrete.•Testing specifications for measuring thermal properties of PCM-concrete are required.•Thermal conductivity and storage of PCM-concrete increases with high conductive PCM-coatings. [Display omitted] Phase change materials (PCMs) have been widely used in building applications as a thermal storage medium for passive thermal regulation and for increasing the efficiency of HVAC systems. Both applications have shown great potential in reducing energy demand or peak loads for both heating and cooling in buildings. Literature shows different ways to incorporate PCMs in the building envelope. This review focuses on the use of PCMs as an additive or replacement material in typical concrete mixtures for building applications. Literature shows that organic paraffin and non-paraffins are the most suitable PCMs for incorporation into concrete mixtures, as they have suitable melting points that match human comfort temperature, high heat capacity, low volume changes during phase change transition, and good chemical and thermal stability. To avoid PCM leakage from the concrete, indirect methods of PCM incorporation in concrete are highlighted, such as encapsulation methods and vacuum impregnation techniques combined with macro-encapsulation methods. Updated information related to the influence of the type of PCM and different incorporation methods on the physical, mechanical and thermal properties of fresh and hardened concrete is presented. Literature shows that by adding PCM to the concrete mixture the heat storage capacity of concrete is generally increased. However, various studies showed that PCMs also have some negative impacts on the physical and mechanical properties of concrete. New relationships between the quantity of PCM and the change in both the thermal and mechanical properties of the concrete are provided. From the reviewed literature, it can be concluded that the potential of using PCM in concrete still requires further research, to study solutions that allow increasing the amount of PCM that is effectively incorporated into concrete and to develop standard testing procedures for measuring the thermal properties of inhomogeneous materials such as PCM-concrete composites.
ISSN:0378-7788
1872-6178
DOI:10.1016/j.enbuild.2019.07.014