TY - JOUR
T1 - Experimental demonstration of an air-source heat pump application using an integrated phase change material storage as a desuperheater for domestic hot water generation,
AU - Emhofer, Johann
AU - Marx, Klemens
AU - Sporr, Andreas
AU - Barz, Tilman
AU - Nitsch, Birgo
AU - Wiesflecker, Michael
AU - Pink, Werner
PY - 2021
Y1 - 2021
N2 - Heat pumps with a three-media refrigerant/phase change material (PCM) water heat exchanger (RPW-HEX),
integrated in the hot superheated section after the compressor, have a promising potential for electric energy
savings. The RPW-HEX operates as a desuperheater that stores the sensible energy provided by the hot gas
during heating and cooling operation for later heat transfer to domestic hot water (DHW) storage devices.
So far, such a system has not yet been implemented and analysed in an overall system suitable for heating,
cooling and DHW generation. In the present work, the operation of a prototypical heat pump with integrated
RPW-HEX connected to three artificial apartments, was demonstrated in the laboratory under controlled
ambient conditions. For this purpose, two RPW-HEX modules with a total storage capacity of about 5kWh
were integrated into an R32 air-source heat pump with a heating power of about 7.7kW at −10 ◦C ambient
temperature and a feed water temperature of 45 ◦C. Technical feasibility and operation with rule-based control
strategies have been successfully demonstrated for realistic use cases. Besides individual tests, the heat pump
was operated over 48 hours with and without RPW-HEX at an ambient temperature of −2 ◦C, a feed water
temperature for the heating system of 40 ◦C. Both systems, achieved the same average COP, but the system with
RPW-HEX was able to provide a 10 K higher average feed water temperature for DHW generation compared
to the system without RPW-HEX. For the same feed water temperatures for DHW generation, an enhancement
of about 3.1% of the average COP can be expected with the current system. This is about 60% of the
theoretically possible value. Furthermore, for a low feed water temperature for heating of about 32 ◦C at
−2 ◦C, an enhancement of the average COP up to 9.4% can be expected for the analysed heating and DHW
scenario with an improved design.
AB - Heat pumps with a three-media refrigerant/phase change material (PCM) water heat exchanger (RPW-HEX),
integrated in the hot superheated section after the compressor, have a promising potential for electric energy
savings. The RPW-HEX operates as a desuperheater that stores the sensible energy provided by the hot gas
during heating and cooling operation for later heat transfer to domestic hot water (DHW) storage devices.
So far, such a system has not yet been implemented and analysed in an overall system suitable for heating,
cooling and DHW generation. In the present work, the operation of a prototypical heat pump with integrated
RPW-HEX connected to three artificial apartments, was demonstrated in the laboratory under controlled
ambient conditions. For this purpose, two RPW-HEX modules with a total storage capacity of about 5kWh
were integrated into an R32 air-source heat pump with a heating power of about 7.7kW at −10 ◦C ambient
temperature and a feed water temperature of 45 ◦C. Technical feasibility and operation with rule-based control
strategies have been successfully demonstrated for realistic use cases. Besides individual tests, the heat pump
was operated over 48 hours with and without RPW-HEX at an ambient temperature of −2 ◦C, a feed water
temperature for the heating system of 40 ◦C. Both systems, achieved the same average COP, but the system with
RPW-HEX was able to provide a 10 K higher average feed water temperature for DHW generation compared
to the system without RPW-HEX. For the same feed water temperatures for DHW generation, an enhancement
of about 3.1% of the average COP can be expected with the current system. This is about 60% of the
theoretically possible value. Furthermore, for a low feed water temperature for heating of about 32 ◦C at
−2 ◦C, an enhancement of the average COP up to 9.4% can be expected for the analysed heating and DHW
scenario with an improved design.
KW - Energy efficient DHW generation Desuperheater PCM Air-source heat pump R32 Storage
KW - Energy efficient DHW generation Desuperheater PCM Air-source heat pump R32 Storage
U2 - 10.1016/j.apenergy.2021.117890
DO - 10.1016/j.apenergy.2021.117890
M3 - Article
SN - 0306-2619
VL - 305
JO - Applied Energy
JF - Applied Energy
ER -