An alternative approach for assessing the benefit of phase change materials in solar domestic hot water systems

• Published in: Solar energy Vol. 158; pp. 875 - 888
• Main Authors: Teamah, H.M., Lightstone, M.F., Cotton, J.S.
• Format: Journal Article
• Language: English
• Published: New York Elsevier Ltd 01.12.2017; Pergamon Press Inc
• Subjects: Energy balance; Energy storage; Enthalpy; Enthalpy porosity; Heat transfer; Hot water heating; Hybrid systems; Impact analysis; Inlet temperature; Mathematical models; Modules; Phase change materials; Porosity; Reduction; Residential energy; Solar collectors; Solar energy; Solar fraction; Systems analysis; Temperature; Thermal energy; Thermal storage; Volume reduction; Phase change materials; Solar fraction; Enthalpy porosity; Thermal storage; Volume reduction
• ISSN: 0038-092X; 1471-1257
• DOI: 10.1016/j.solener.2017.10.033

•Hybrid system containing water and phase change materials is simulated.•Solar fraction of hybrid system is compared to water only system.•PCM enhances solar fraction when the tank is undersized for the demand.•PCM increases pump run time and reduces collector losses. Phase change materials (PCM) for thermal energy storage in solar energy systems have been the subject of a great deal of research in the literature. Despite this, the research results pertaining to the efficacy of PCMs in enhancing system solar fraction are mixed. The current paper explores this issue numerically within a systems context. A typical solar domestic hot water system is considered. The PCMs are introduced as vertical cylindrical modules contained within the water tank, thus forming a hybrid PCM/water thermal storage. Water flowing along the length of tank is used as the heat transfer fluid. A model was developed based on the enthalpy-porosity method to solve for the phase change process within the PCM modules. The model was thoroughly validated and verified and predictions were in good agreement (less than 5% deviation) with results from the literature. The hybrid tank model was linked with the collector performance and the system was tested for typical days of Canadian weather with a dispersed demand profile. The solar fraction of the hybrid system was compared to that for an identical system using water-only as the thermal storage medium. The system analysis explores the impact of storage volume on solar fraction for systems with and without PCMs included. The systems approach is critical since it allows for the coupled effects of the thermal storage, solar collector, and household load to be incorporated. The analysis clearly shows that incorporation of PCMs into the thermal storage results in enhanced solar fraction at undersized tank volumes relative to the demand. In contrast, as the tank volume is increased, the benefit of the PCMs diminishes and identical performance is obtained between the two systems at large volumes. An energy balance of the system shows that, despite marginally increased heat losses from the hybrid tank, the benefits of the hybrid storage at small storage volumes are due to the reduction in the collector fluid inlet temperature which increases the pump run time and thus the solar energy collected and reduction of collector losses.