FINNED ELLIPTIC TUBES HEAT EXCHANGERS IN THE TURBULENT REGIME CONSTRUCTAL DESIGN

Authors

  • MARCUS PEREIRA Department of Mechanical Engineering, Graduate Program in Materials Science Engineering (PIPE), and Sustainable Energy Research & Development Center (NPDEAS), UFPR – Federal University of Paraná, CP 19011, 81531–980, Curitiba, PR, Brazil. Author
  • JEFERSON SOUZA Graduate Program of Ocean Engineering, School of Engineering, Federal University of Rio Grande – FURG, Italy Avenue, km 8, CP. 474, Rio Grande, RS, Brazil. Author
  • JOSE VIRIATO COEHLO VARGAS Department of Mechanical Engineering, Energy and Sustainability Center, and Center for Advanced Power Systems, Florida State University, Tallahassee, Florida 32310–6046, USA. Author
  • DIOGO PITZ Department of Mechanical Engineering, Graduate Program in Materials Science Engineering (PIPE), and Sustainable Energy Research & Development Center (NPDEAS), UFPR – Federal University of Paraná, CP 19011, 81531–980, Curitiba, PR, Brazil. Author
  • JUAN ORDONEZ Department of Mechanical Engineering, Energy and Sustainability Center, and Center for Advanced Power Systems, Florida State University, Tallahassee, Florida 32310–6046, USA. Author
  • VANESSA MERIO KAVA Department of Genetics, Graduate Program in Genetics (PPG-GEN), and Sustainable Energy Research & Development Center (NPDEAS), UFPR – Federal University of Paraná, CP 19011, 81531–980, Curitiba, PR, Brazil. Author

DOI:

https://doi.org/10.59277/CLC.2024.31

Keywords:

Heat transfer, Numerical simulation, Refrigeration, Tube banks

Abstract

This work seeks numerically the heat exchanger structure direction of evolution in time, i.e., the general optimal that maximizes the total heat transfer rate between a fixed volume arrangement of finned tubes and a turbulent external flow governed by a pressure difference, both for circular and elliptic tube arrays. In this way, the dynamic, ever-changing heat exchanger design that provides easier access to the currents that flow through it is sought for any time reality (e.g., geometry, materials, environment), according to Constructal law. The optimization procedure began by recognizing the limited availability of the design space as a fixed volume constraint. The three-way optimized (3wo) arrangement concerning tube-to-tube distance, eccentricity, and fin density was found as (S/2b, e, ϕf)3wo ≅ (0.5; 0.4; 0.094). A relative heat transfer gain of up to 38% was noted with the elliptic compared to the 3wo circular arrangement, demonstrating that elliptical tube arrangements have potential for considerably better performance and lower cost than traditional circular arrangements. 

References

(1) Matos R.S., Vargas J.V.C., Rossetim M.A., Pereira M.V.A., Pitz D.B., Ordonez J.C., Performance comparison of tube and plate-fin circular and elliptic heat exchangers for HVAC-R systems, Applied Thermal Engineering, 184, p. 116288 (2021).

(2) Macchitella S., Colangelo G., Starace G., Performance Prediction of Plate-Finned Tube Heat Exchangers for Refrigeration: A Review on Modeling and Optimization Methods, Energies, 16, p. 1948 (2023).

(3) Bejan A., Lorente S., Constructal law of design and evolution: Physics, biology, technology, and society. J. Appl. Phys., 113, p. 151301 (2013).

(4) Bejan A., Tsatsaronis G., Purpose in thermodynamics. Energies, 14, 2, p. 408 (2021).

(5) Bejan A., Entropy Generation Minimization, CRC Press, Boca Raton, Florida, USA, 1995.

(6) Martinho L.C.S., Vargas, J.V.C., Balmant W., Ordonez J.C., A single stage absorption refrigeration system dynamic mathematical modeling, adjustment and experimental validation, Int. J. Refrigeration, 68, pp. 130–144 (2016).

(7) Pereira M.V.A., Modeling, Simulation and Optimization of Finned Tubes Heat Exchangers in Turbulent Regime, PhD Dissertation, Federal University of Parana, Curitiba, Brazil, 2018.

Downloads

Published

18.12.2024

Issue

Vol. 2024 No. 1 (2024): CONSTRUCTAL LAW CONFERENCE | DESIGN IN NATURE AND EVOLUTION

Section

Design in nature

How to Cite

FINNED ELLIPTIC TUBES HEAT EXCHANGERS IN THE TURBULENT REGIME CONSTRUCTAL DESIGN. (2024). 14th CONSTRUCTAL LAW CONFERENCE | 10-11 October 2024, Bucharest, Romania, 2024(1), 121-124. https://doi.org/10.59277/CLC.2024.31