Experimental characterization of the coupling and heating performance of a CO2 water-to-water heat pump and a water storage tank for domestic hot water production system
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AutorSánchez Velasco, Francisco Javier; Haddouche, Mohammed Reda; Illán Gómez, Fernando; García Cascales, José Ramón
Área de conocimientoMecánica de Fluidos
PatrocinadoresThis work has been performed in the context of the project in the project “Maximisation of the efficiency and minimisation of the environmental impact of heap pumps for the decarbonisation of heating and domestic hot water production in nearly zero energy buildings” ENE2017- 83665-C2-2-P, Funded by the Ministry of Economy and Competitiveness, Spain and the support of the European Regional Development Fund. The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
Realizado en/conUniversidad Politécnica de Cartagena
Fecha de publicación2022-04-18
Cita bibliográficaF.J.S. Velasco, M.R. Haddouche, F. Illán-Gómez, J.R. García-Cascales, Experimental characterization of the coupling and heating performance of a CO2 water-to-water heat pump and a water storage tank for domestic hot water production system, Energy and Buildings, Volume 265, 2022, 112085, ISSN 0378-7788, https://doi.org/10.1016/j.enbuild.2022.112085.
Revisión por paresSI
Palabras claveHeat pump
Hot water production
This work presents an experimental study of the dynamic performance of a CO2 water-to-water heat pump in a domestic hot water production system. A facility was developed and used to characterize the time evolution of the COP of this heat pump, the heating and stratification processes of the hot-water storage tank, and the global COP of the system. Results showed that, when heating the water storage tank, strategies based on promoting stratification to reach Ri ∼40, such as the use of vertical tank filling velocities ∼ 10-4 m·s−1 with low water flow rates between the tank and the heat pump gas cooler, permits an increase of ∼12.4% in the system global COP and a reduction of ∼16% of the compressor energy consumption compared to other strategies. However, strategies based on considering higher water flow rates (i.e. Ri ∼1) increase the thermal energy available in the tank (∼6% when flow rate and increases a factor 3.6) but enhance the water mixing and extend the heating time which reduces ...
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