TY - JOUR
T1 - Performance Review of Solar-Assisted Heat Pump Systems Using Solar Collectors, PV, and PVT Technologies
AU - Zohri, Muhammad
AU - Prabowo,
AU - Suwarno,
AU - Fudholi, Ahmad
AU - Suyono, Tri
AU - Priandana, Eka Rakhman
AU - Utomo, Yusuf Suryo
N1 - Publisher Copyright:
© 2023 International Information and Engineering Technology Association. All rights reserved.
PY - 2023/6
Y1 - 2023/6
N2 - Heat pumps (HP) can be used for a variety of residential, commercial, and industrial applications and offer a cost-effective replacement for conventional heat recovery systems. Hybrid systems that can be utilized for drying, heat storage, and water heating include solar-assisted heat pumps. Solar energy as a heat source for heat pump dryers improves performance and energy efficiency. This review aims to examine the concept of a solar collector, PV, and PVT technologies-assisted heat pump. The use of solar collectors to assist heat pump technology is a longstanding practice that remains in use today. Solar collectors that utilize direct solar heat sources and convert them into warm water or space heating are highly efficient. The concept of a PV and PVT-assisted heat pump is gaining popularity. The heat source utilized can be either single or multiple. Integrating a heat pump with a PVT as an evaporator result in higher heat performance. Using multiple heat sources is a more effective way to meet the cooling or heating requirements than relying on a single heat source. This review focuses on the mathematical modeling of a heat pump system integrated with PVT. Aspects of the mathematical model are critical for estimating the performance of heat pump systems in conjunction with solar collectors, PV, and PVT technologies. Readers who design and use heat pump technology must comprehend efficiency, COP, and configuration models.
AB - Heat pumps (HP) can be used for a variety of residential, commercial, and industrial applications and offer a cost-effective replacement for conventional heat recovery systems. Hybrid systems that can be utilized for drying, heat storage, and water heating include solar-assisted heat pumps. Solar energy as a heat source for heat pump dryers improves performance and energy efficiency. This review aims to examine the concept of a solar collector, PV, and PVT technologies-assisted heat pump. The use of solar collectors to assist heat pump technology is a longstanding practice that remains in use today. Solar collectors that utilize direct solar heat sources and convert them into warm water or space heating are highly efficient. The concept of a PV and PVT-assisted heat pump is gaining popularity. The heat source utilized can be either single or multiple. Integrating a heat pump with a PVT as an evaporator result in higher heat performance. Using multiple heat sources is a more effective way to meet the cooling or heating requirements than relying on a single heat source. This review focuses on the mathematical modeling of a heat pump system integrated with PVT. Aspects of the mathematical model are critical for estimating the performance of heat pump systems in conjunction with solar collectors, PV, and PVT technologies. Readers who design and use heat pump technology must comprehend efficiency, COP, and configuration models.
KW - coefficient of performance
KW - heat pumps
KW - performance models
KW - photovoltaic thermal
KW - photovoltaics
KW - solar collectors
KW - system configuration
UR - http://www.scopus.com/inward/record.url?scp=85168002487&partnerID=8YFLogxK
U2 - 10.18280/ijht.410318
DO - 10.18280/ijht.410318
M3 - Article
AN - SCOPUS:85168002487
SN - 0392-8764
VL - 41
SP - 657
EP - 665
JO - International Journal of Heat and Technology
JF - International Journal of Heat and Technology
IS - 3
ER -