Study on the Performance of a Ground Source Heat Pump System Assisted by Solar Thermal Storage
Abstract
:1. Introduction
2. System Summary and Operation Strategy
2.1. System Summary
2.2. Operation Strategy
2.2.1. Heating Mode (8 P.M. < t < 5 A.M.)
2.2.2. Solar Thermal Storage Mode (6 A.M. < t < 6 P.M.)
3. Simulation Introduction
3.1. System Summary
3.2. Simulation Conditions
Items | Unit | Value |
---|---|---|
Building | ||
Design temperature | °C | 22 |
Scale | m | 10×10×3 |
U-value of external wall, roof, floor | W/(m2K) | 0.418, 0.193, 0.583 |
Solar collectors | ° | |
Area | m2 | 50 |
Titled angle | 45 | |
Flow rate | kg/h | 3600 |
Ground heat exchangers | ||
Inner diameter | mm | 29 |
Outer diameter | mm | 35 |
Center -to-center half distance | mm | 50 |
Pipe thermal conductivity | W/(m·K) | 0.41 |
Flow rate(Heating mode) | kg/h | 2500 |
Flow rate(Heat storage mode) | kg/h | 2000 |
Boreholes | ||
Fill thermal conductivity | W/(m·K) | 1.5 |
Number | - | 3 |
Depth | m | 100 |
Diameter | mm | 200 |
Ground | ||
Soil thermal conductivity | W/(m·K) | 3.5 |
Soil density | kg/m3 | 3000 |
Heat capacity | kJ/(m3K) | 2920 |
System operation time | ||
Heating mode | h | 20:00~5:00 |
Storage mode | h | 6:00~18:00 |
4. Results and Discussion
4.1. Comparison with a General Ground Source Heat Pump System
Month | Heat Exchange Rate (W/m) | Heat Source Temperature (°C) | Heat Pump COP | |||
---|---|---|---|---|---|---|
GHPS | SAGHPS | GHPS | SAGHPS | GHPS | SAGHPS | |
November | 41.1 | 51.4 | 9.1 | 9.8 | 4.8 | 5.1 |
December | 35.4 | 43.6 | 7.7 | 8.9 | 4.3 | 4.7 |
January | 32.8 | 39.8 | 6.9 | 8.6 | 4.2 | 4.6 |
February | 31.3 | 39.8 | 6.6 | 8.5 | 4.1 | 4.5 |
March | 30.8 | 47.0 | 6.6 | 9.3 | 4.0 | 4.9 |
Average | 33.8 | 43.3 | 7.3 | 8.9 | 4.3 | 4.7 |
4.2. Performance Analysis with Different Solar Collector Areas
Case | Collector Area (m2) | Heat Exchange Rate (W/m) | Heat Source Temperature (°C) | Heat Pump COP | Extraction Energy (kW∙h) | Injection Energy (kW∙h) |
---|---|---|---|---|---|---|
1 | 40 | 41.3 | 8.64 | 4.60 | 9999.6 | 6829.7 |
2 | 50 | 43.3 | 8.91 | 4.69 | 10062.9 | 8110.0 |
3 | 60 | 44.8 | 9.11 | 4.75 | 10319.6 | 9286.6 |
4 | 70 | 46.4 | 9.33 | 4.81 | 10341.5 | 10333.2 |
5 | 80 | 47.6 | 9.52 | 4.86 | 10498.5 | 11299.1 |
6 | 90 | 48.9 | 9.70 | 4.90 | 10576.3 | 12164.9 |
System | Investment Costs (Thousand Won) | Operation Costs (Thousand Won) |
---|---|---|
ASHPS | 4000 | 3344.9 |
GSHPS | 16858 | 1158.8 |
Case 2 (50 m2) | 21858 | 1087.0 |
Case 4 (70 m2) | 23858 | 1053.9 |
Case 6 (90 m2) | 25858 | 992.6 |
4.3. Performance Analysis with Different Conductivity of Grouting
Case | Thermal Conductivity (W/(m∙K)) | Heat Exchange Rate (W/m) | Heat Source Temperature (°C) | Heat Pump COP | Extraction Energy (kW∙h) | Injection Energy (kW∙h) |
---|---|---|---|---|---|---|
1 | 0.9 | 36.4 | 7.84 | 4.38 | 9511.4 | 7727.8 |
2 | 1.2 | 40.2 | 8.48 | 4.55 | 9941.7 | 7970.6 |
3 | 1.5 | 43.3 | 8.91 | 4.69 | 10,062.9 | 8110.0 |
4 | 1.8 | 45.5 | 9.22 | 4.77 | 10,265.6 | 8212.7 |
5 | 2.1 | 47.1 | 9.45 | 4.84 | 10,490.8 | 8291.5 |
4.4. Performance Analysis with Different Weather Conditions
City | Heat Exchange Rate (W/m) | Heat Source Temperature (°C) | Heat Pump COP | Extraction Energy (kW∙h) | Injection Energy (kW∙h) |
---|---|---|---|---|---|
Shanghai | 48.6 | 9.5 | 4.94 | 7348.5 | 7313.5 |
Seoul | 43.3 | 8.9 | 4.69 | 10062.9 | 8110.0 |
Sapporo | 40.1 | 8.5 | 4.56 | 10966.1 | 7000.2 |
5. Conclusions
- The ground heat pump system assisted by solar thermal can effectively maintain the soil temperature balance. In addition, under the same operation conditions, the performance of SAGHPS is better than that of GSHPS. During the entire operation time, the heat exchange rate and heat pump COP of SAGHPS were 43.3 W/m and 4.7. Compared with GSHPS, these values increased by 28.1% and 9.3%, respectively.
- With the increase of the collector area and the upgraded heating performance of the system, the investment costs increased relatively. From the result of the LCC assessment, when the solar collector area increased from 50 m2 to 90 m2, the payback period of SAGHPS would be in the range of 10 to 12 years.
- In contrast to other methods, using a high thermal conductivity grouting not only increases the heating performance of the heat pump, but also increases the energy use ratio.
- In different locations, because of the climatic differences, the performance of the system also differs. In a subtropical area (Shanghai), the system achieves a better heating performance than that in a cold area (Sapporo). However, in the cold area, the system achieved the best solar storage ratios, which were 55.4%, 0.6%, and 6.5% higher than those of Seoul and Shanghai.
- In the next research stage, the simulation results will be verified through a demonstration experiment. Also, in order to establish the optimum design method of the suggested system, more case studies will be conducted.
Acknowledgments
Author Contributions
Conflicts of Interest
Nomenclature
VDST | The volume of the storage (m3) |
n | Borehole number |
h | The length of borehole (m) |
B | Borehole spacing (m) |
Tr | Indoor temperature (°C) |
Tst | Average temperature of storage tank (°C) |
Ts | Solar source temperature (°C) |
Tg | Ground source temperature (°C) |
COPHP | The heat pump coefficient of performance |
Cap | Heat pump heating capacity (kW) |
P | Power consumption of the system (kW) |
PHP | Power consumption of the heat pump (kW) |
Q | Energy production of system (kW) |
Qheat | Heat transfer rate (kW) |
Qabsorbed | Energy absorbed by the heat pump (kW) |
Qinjection | Solar storage energy (kW) |
Qsolar | Energy absorbed by solar collector (kW) |
Tsource, in | Temperature of liquid entering the source side of the heat pump (°C) |
Tsource, out | Temperature of liquid exiting the source side of the heat pump (°C) |
Tload, in | Temperature of liquid entering the load side of the heat pump (°C) |
Tload, out | Temperature of liquid exiting the load side of the heat pump (°C) |
Tfluid, in | Inlet fluid temperature of the borehole (°C) |
Tfluid, out | Outlet fluid temperature of the borehole (°C) |
Tb | Temperature at borehole wall (°C) |
m | Flow rate of the liquid (kg/h) |
c | Specific heat of the liquid (kJ/kg·K) |
t | Operation time(0~24 h) |
q | Heat exchange rate of ground heat exchanger (W/m) |
β | Damping factor |
v | Three-way valve |
P | Circulation pump |
η | Solar storage ratio |
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Nam, Y.J.; Gao, X.Y.; Yoon, S.H.; Lee, K.H. Study on the Performance of a Ground Source Heat Pump System Assisted by Solar Thermal Storage. Energies 2015, 8, 13378-13394. https://doi.org/10.3390/en81212365
Nam YJ, Gao XY, Yoon SH, Lee KH. Study on the Performance of a Ground Source Heat Pump System Assisted by Solar Thermal Storage. Energies. 2015; 8(12):13378-13394. https://doi.org/10.3390/en81212365
Chicago/Turabian StyleNam, Yu Jin, Xin Yang Gao, Sung Hoon Yoon, and Kwang Ho Lee. 2015. "Study on the Performance of a Ground Source Heat Pump System Assisted by Solar Thermal Storage" Energies 8, no. 12: 13378-13394. https://doi.org/10.3390/en81212365
APA StyleNam, Y. J., Gao, X. Y., Yoon, S. H., & Lee, K. H. (2015). Study on the Performance of a Ground Source Heat Pump System Assisted by Solar Thermal Storage. Energies, 8(12), 13378-13394. https://doi.org/10.3390/en81212365