Optimisation of transcritical R744 gas coolers with Microgroove smaller diameter copper tubes

1. Optimization of Transcritical R744 Gas Coolers with MicroGroove Smaller Diameter Copper Tubes Heat Transfer Technologies

2. Content: • Gas cooler design considerations • Gas cooler design examples 1-3 • Copper alloys for use in CO2 systems • Gas cooler case study • Applications

3. Gas Cooler design considerations Tube wall thickness and yield strength needs to accommodate maximum operating pressures. • 45 – 60 – 85 bar for unit coolers • 130 bar for gas coolers. Source: LU-VE Group

4. Standard design: 45 bar MAX CO2 gas cooler: 120 bar MAX • Withstands high pressure without special copper alloy or very large tube wall thickness. • Low viscosity of CO2 allows for smaller tubes with long circuits, allowing for optimal pressure drops. • Smaller tubes reduce internal volume and refrigerant charge, allowing for compact coils. Tube Pattern: 20 mm x 17,32 mm Using 5 mm OD tube Gas Cooler design considerations Source: LU-VE Group

5. Two approaches to gas cooler design: A. Modify pressure range of existing (HFC) condensers to accommodate higher pressure (e.g., change tube thickness) B. Optimize design capitalizing on the peculiar properties of CO2 • Smaller tubes (e.g., 5 mm OD) • Compact geometry • Spray system Adiabatic system Gas Cooler design considerations Source: LU-VE Group

6. • High operating pressure: 130 bar • Low CO2 outlet temperature • Air outlet temperature can be increased due to the large ΔT (counter flow). This means lower air flow, energy consumption, noise level. • Redesign circuits and number of supply inlets due to the difference in viscosity of CO2 compared to HFC fluids. Gas Cooler design considerations Source: LU-VE Group

7. Gas Cooler design example 1 Source: LU-VE Group

8. Gas Cooler design example 2 Source: LU-VE Group

9. CO2 Gas Cooler Unit 5 mm tube 5/16 inch Tube Percent Drop Capacity BTU/h (kilowatt) 43,000 (12.6) 43,000 (12.6) Design Pressure PSIA (MPa) 1005 (68.4) 1005 (68.4) Coil Size inch x inch (cm x cm) 18 x 37 (46 x 94) 18 x 37 (46 x 94) Rows 4 4 Fin Density fins / inch 15 12.5 Tube Pattern inch x inch (mm x mm) 0.75 x 0.45 (19 x 11.4) 1.00 x 0.625 (25 x 15.9) Tube Material copper Copper Tube OD Inch (mm) 0.197 (5.0) 0.3125 (7.94) Tube Wall Inch (mm) 0.040 (1.0) 0.049 (1.25) Tube Weight Pounds (kg) 24.5 (11.1) 37.7 (17.1) 35% Fin Material aluminum aluminum Fin Thickness Inches (mm) 0.0039 (0.10) 0.0045 (0.114) Fin Weight Pounds (kg) 7.5 (3.4) 9.5 (4.3) 21% Total Internal Volume liter 1.2 2.2 45% Source: Super Radiator Coils Gas Cooler design example 3

10. Copper alloys for CO2 systems UNS Alloy C19400 Min. 97.0% Cu; 2.1 to 2.6% Fe • Good thermal conductivity due to high copper content • Increased strength and temperature stability • UTS min @ 60 ksi versus Std. Copper @ 36 ksi • Corrosion resistance slightly improved • Commonly used in transmission lines from cooler-to- rack and rack-to-cooler • Reduce tube wall thickness in gas coolers For more Information: 2019 ATMO America Presentation by Yoram Shabtay

11. Gas Cooler Case study R404A CO2 CO2 Number of fans 3 3 1 Front coil area, m2 5.28 5.28 2.56 Number of rows 3 3 6 Number of inlets 66 (std) 22 21 Fan positioning induced-draft induced- draft forced- draft Cooler outlet temperature, at equal power (air at 25°C) 40 °C (condensation) 25.3 °C (ΔT = 0.3) 28.8 °C (ΔT = 3.8) Or: (relative) thermal rating cooler outlet temp. = 30 °C 100 (ΔT = 3K) 158 (ΔT = 3K) 96.0 (ΔT = 3K) R404A condenser, 170kW capacity with initial ΔT of 15 K, Compared to CO2 gas coolers of the same power range Source: LU-VE Group

12. Gas Cooler Case study This achievement was made possible because of the design strategy adopted by LU-VE, consisting of the utilization of high performance heat transfer surfaces and of miniaturized geometries (small diameter tubes) even for large heat exchangers. COOP WETTINGEN - Zurig - Switzerland Gas cooler Source: LU-VE Group

13. Gas cooler with 5 mm MicroGroove tubes technology (Chillventa 2018) Gas Cooler Case study Source: LU-VE Group

14. Plus Supermarket Gorinchem, Netherlands Case Study, ATMO Europe 2018 Livio Perrotta, LU-VE Group Gas Cooler applications Source: LU-VE Group

15. Plus Supermarket Gorinchem, Netherlands Gas Cooler applications Source: LU-VE Group

16. Plus Supermarket Gorinchem, Netherlands CO2 CO2 Gas Cooler applications Source: LU-VE Group

17. Small diameter copper tubes gas cooler Conclusions • Reduce refrigerant charge • Reduce weight and cost • Improve efficiency For additional info visit www.microgroove.net

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