Effect of Compressor-Discharge-Cooler Heat-Exchanger Length Using Condensate Water on the Performance of a Split-Type Air Conditioner Using R32 as Working Fluid
Abstract
:1. Introduction
2. System and Configuration
3. Experimental Facility and Method
- Measurement of A/C performance without a heat exchanger standard).
- Measurement of A/C performance using a heat exchanger with a length of 0.18 m.
- Measurement of A/C performance using a heat exchanger with a length of 0.20 m.
- Measurement of A/C performance using a heat exchanger with a length of 0.22 m.
4. Analysis of the Experimental Data
4.1. Effect on the Condenser Outlet Temperature
4.2. Effect on the Cooling Capacity
4.3. Effect on the Input Power
4.4. Effect on the Coefficient of Performance
4.5. Regression Analysis
5. Conclusions
- By applying HX as the subcooler, the degree of subcooling improved, with average improvements of 0.9, 1.5 and 4.5 K, at lengths of 18, 20 and 22 cm, respectively.
- The improvement in the degree of subcooling led to an increase in cooling capacity.
- Compared to the A/C without a subcooler, average increments in cooling capacity of 5.9, 8.9 and 14.9% and average net-input-power reductions of 2.4, 4.8 and 9.8% were achieved for the A/C with 18-, 20- and 22-centimeter-long HX, respectively.
- Compared to the method of evaporative cooling proposed by previous researchers, this method is superior in terms of its simplicity, its lack of requirement of additional input power and its ability to produce significant COP improvements of up to 27.3% (on average, for the longest HX, of 22 cm).
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
Abbreviations
A | surface area of the evaporator, m2 |
A/C | air conditioning |
COP | coefficient of performance |
average coefficient of performance | |
specific enthalpy, kJ/kg | |
HX | heat exchanger |
I | electrical current, A |
L | length of heat-exchanger pipe, m |
η | isentropic efficiency, % |
temperature difference, °C | |
GWP | global-warming potential |
ODP | ozone-depleting potential |
refrigerant-mass-flow rate, kg/s | |
ρ | air density, kg/m3 |
P | refrigerant pressure, bar |
PF | power factor |
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Working Fluid | The Compressor Discharge Temperature (°C) | ||||
---|---|---|---|---|---|
= 0.50 | = 0.55 | = 0.60 | = 0.65 | = 0.70 | |
R410A | 80.8 | 76.2 | 72.6 | 69.5 | 66.9 |
R404A | 60.2 | 57.2 | 54.7 | 52.6 | 51.0 |
R407C | 73.7 | 69.3 | 65.5 | 62.4 | 57.9 |
R22 | 83.5 | 78.4 | 74.1 | 70.5 | 67.7 |
R32 | 89.8 | 84.1 | 80.1 | 75.2 | 70.1 |
Working Fluid | GWP | ODP |
---|---|---|
R410A | 2088 | 0 |
R404A | 3300 | 0 |
R22 | 1810 | 0.055 |
R32 | 675 | 0 |
No | Equipment | Measurements | Accuracy | Range |
---|---|---|---|---|
1. | K-type thermocouple | Temperature | ±0.1 °C | −50 to 1300 °C |
2. | Pressure gauge | High pressure | ±0.5 bar | −1 to 38 bar |
3. | Pressure gauge | Low pressure | ±0.1 bar | −1 to 55 bar |
4. | Pitot-tube anemometer | Air velocity | ±0.05 m/s | −15 to 15 in H2O |
5. | Clamp-on-ammeter | Electrical current | ±0.1 A | 0 to 600 V |
6. | Voltmeter | Electrical potential | ±1 V | 0 to 400 A |
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Sumeru, K.; Pramudantoro, T.P.; Setyawan, A.; Muliawan, R.; Tohir, T.; bin Sukri, M.F. Effect of Compressor-Discharge-Cooler Heat-Exchanger Length Using Condensate Water on the Performance of a Split-Type Air Conditioner Using R32 as Working Fluid. Energies 2022, 15, 8024. https://doi.org/10.3390/en15218024
Sumeru K, Pramudantoro TP, Setyawan A, Muliawan R, Tohir T, bin Sukri MF. Effect of Compressor-Discharge-Cooler Heat-Exchanger Length Using Condensate Water on the Performance of a Split-Type Air Conditioner Using R32 as Working Fluid. Energies. 2022; 15(21):8024. https://doi.org/10.3390/en15218024
Chicago/Turabian StyleSumeru, Kasni, Triaji Pangripto Pramudantoro, Andriyanto Setyawan, Rizki Muliawan, Toto Tohir, and Mohamad Firdaus bin Sukri. 2022. "Effect of Compressor-Discharge-Cooler Heat-Exchanger Length Using Condensate Water on the Performance of a Split-Type Air Conditioner Using R32 as Working Fluid" Energies 15, no. 21: 8024. https://doi.org/10.3390/en15218024
APA StyleSumeru, K., Pramudantoro, T. P., Setyawan, A., Muliawan, R., Tohir, T., & bin Sukri, M. F. (2022). Effect of Compressor-Discharge-Cooler Heat-Exchanger Length Using Condensate Water on the Performance of a Split-Type Air Conditioner Using R32 as Working Fluid. Energies, 15(21), 8024. https://doi.org/10.3390/en15218024