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Abstract: Analyzing the articles on heat transfer and fluid flow one can say that all are applied to specific environmental or engineering problems. The articles are encountered in fluid dynamics and/or heat transfer in machines, production and exploration process, environment, and other related areas of mechanical engineering. The authors of described solutions of scientific and industrial relevance in a specific field of heat transfer and fluid flow, including technical devices, nanofluids, industrial processes, dedicated perforations or mechanically deformed pipes, the transport of solid particles, etc. These articles serve as catalysts for future directions and priorities in numerical heat
transfer and fluid flow. Some articles dealt with simulations, while others presented their own experimental data. The articles, which dealt with simulations, contained a physical model with major assumptions such as the physical properties of the flowing medium, geometry of the flow domain, boundary, and initial conditions, and then a mathematical model. Mathematical models were formulated using conservation laws, such as equations of continuity, N-S, and energy. The authors formulated the set of equations for a variety of applications and solved them numerically, taking into account the convergence criteria and ensuring a mesh-independent solution. All simulations were performed using commercial software, and most of the mathematical models were properly validated.
B I B L I O G R A F I A1. Bartosik, A. Numerical heat transfer and fluid flow: A review of contributions to the special issue. Energies 2022, 15, 2922.
2. Patankar, S.V. (Ed.) Numerical Heat Transfer and Fluid Flow
Taylor and Frances Inc.: Abingdon, UK, 1980
p. 2014.
3. Spalding, D.B. Turbulence Models for Heat Transfer
Report HTS/78/2
Department of Mechanical Engineering, Imperial College of London: London, UK, 1978.
4. Spalding, D.B. Turbulence Models—A Lecture Course
Report HTS/82/4
Department of Mechanical Engineering, Imperial College of London: London, UK, 1983.
5. Castelvecchi, D. Mysteries of turbulence unravelled. Nature 2017, 548, 382–383.
6. Klebert, P.
Su, B. Turbulence and flow field alterations inside a fish sea cage and its wake. Appl. Ocean Res. 2020, 98, 102–111.
7. Zong, Y.
Bai, D.
Zhou, M.
Zhao, L. Numerical studies on heat transfer enhancement by hollow-cross disk for cracking coils. Chem. Eng. Process. Process Intensif. 2019, 135, 82–92.
8. Nakhchi, M.E.
Esfahani, J.A. Numerical investigation of heat transfer enhancement inside heat exchanger tubes fitted with perforated hollow cylinders. Int. J. Therm. Sci. 2020, 147, 106153.
9. Ahn, K.
Song, J.C.
Lee, J.S. Dependence of conjugate heat transfer in ribbed channel on thermal conductivity of channel wall: An LES Study. Energies 2021, 14, 5698.
10. Pandey, L.
Singh, S. Numerical analysis for heat transfer augmentation in a circular tube heat exchanger using a triangular perforated Y-shaped insert. Fluids 2021, 6, 247.
11. Hagiwara, Y. Effects of bubbles, droplets or particles on heat transfer in turbulent channel flows. Flow Turbul. Combust. 2011, 86, 343–367.
12. Hamed, H.
Mohhamed, A.
Khalefa, R.
Habeeb, O. The effect of using compound techniques (passive and active) on the double pipe heat exchanger performance. Egypt. J. Chem. 2021, 64, 2797–2802.
13. Zhao, J.
Zhang, B.
Fu, X.
Yan, S. Numerical study on the influence of vortex generator arrangement on heat transfer enhancement of oil-cooled motor. Energies 2021, 14, 6870.
14. Urbanowicz, K.
Bergant, A.
Stosiak, M.
Deptuła, A.
Karpenko, M. Navier-Stokes solutions for accelerating pipe flow—A review of analytical models. Energies 2023, 16, 1407.
15. Bhanvase, B.
Barai, D. Nano Fluid for Heat and Mass Transfer—Fundamentals, Sustainable Manufacturing and Applications
Academic Press: London, UK, 2021
p. 448.
16. Cieśliński, J. Numerical modelling of forced convection of nanofluids in smooth, round tubes: A review. Energies 2022, 15, 7586.
17. Lotfi, R.
Saboohi, Y.
Rashidi, A.M. Numerical study of forced convective heat transfer of nanofluids: Comparison of different approaches. Int. Commun. Heat Mass Transf. 2010, 37, 74–78.
18. Mokmeli, A.
Saffar-Avval, M. Prediction of nanofluid convective heat transfer using the dispersion model. Int. J. Therm. Sci. 2010, 49, 471–478.
19. Maïga, S.
Nguyen, C.T.
Galanis, N.
Roy, G. Heat transfer behaviours of nanofluids in a uniformly heated tube. Superlattices Microstruct. 2004, 35, 543–557.
20. Cantat, I.
Cohen-Addad, S.
Elias, F.
Graner, F.
Höhler, R.
Pitois, O.
Rouyer, F.
Saint-Jalmes, A. Foams: Structure and Dynamics
OUP: Oxford, UK, 2013.
21. Mobarak, M.
Gatternig, B.
Delgado, A. On the simulations of thermal liquid foams using Lattice Boltzmann method. Energies 2023, 16, 195.
22. Shen, L.
Xu, S.
Bai, Z.
Wang, Y.
Xie, J. Experimental study on thermal and flow characteristics of metal foam heat pipe radiator. Int. J. Therm. Sci. 2021, 159, 106572.
23. Shan, X.
Liu, B.
Zhu, Z.
Bennacer, R.
Wang, R.
Theodorakis, P.E. Analysis of the heat transfer in electronic radiator filled with metal foam. Energies 2023, 16, 4224.
24. Ferreira, P.H.
Araújo, T.B.
Carvalho, E.O.
Fernandes, L.D.
Moura, R.C. Numerical investigation of flow past bio-inspired wavy leading-edge cylinders. Energies 2022, 15, 8993.
25. Mousavi Ajarostaghi, S.S.
Zaboli, M.
Javadi, H.
Badenes, B.
Urchueguia, J.F. A Review of recent passive heat transfer enhancement methods. Energies 2022, 15, 986.
26. Kügele, S.
Mathlouthi, G.O.
Renze, P.
Grützner, T. Numerical simulation of flow and heat transfer of a discontinuous single started helically ribbed pipe. Energies 2022, 15, 7096.
27. Virgilio, M.
Mayo, I.
Dedeyne, J.
Geem, K.V.
Marin, G.
Arts, T. Effects of 2-D and 3-D helical inserts on the turbulent flow in pipes. Exp. Therm. Fluid Sci. 2020, 110, 109923.
28. Virgilio, M.
Mayo, I.
Dedeyne, J.
Geem, K.V.
Marin, G.
Arts, T. Influence of obstacles on the wall heat transfer for 2D and 3D helically ribbed pipes. Int. J. Heat Mass Transf. 2020, 148, 119087.
29. Lee, C.S.
Shih, T.I.P.
Bryden, K.M.
Dalton, R.P.
Dennis, R.A. Strongly heated turbulent flow in a channel with pin fins. Energies 2023, 16, 1215.
30. Kaczmarski, K. Identification of transient steam temperature at the inlet of the pipeline based on the measured steam temperature at the pipeline outlet. Energies 2022, 15, 5804.
31. Li, P.-W.
Chan, C.L. Thermal Energy Storage Analyses and Designs
Academic Press: London, UK, 2017.
32. Taler, D.
Taler, J.
Sobota, T.
Tokarczyk, J. Cooling modelling of an electrically heated ceramic heat accumulator. Energies 2022, 15, 6085.
33. Russell, P.S. Photonic-crystal fibers. J. Light. Technol. 2006, 24, 4729–4749.
34. Luzi, G.
Lee, S.
Gatternig, B.
Delgado, A. An asymptotic energy equation for modelling thermo fluid dynamics in the optical fibre drawing process. Energies 2022, 15, 7922.
35. Fitt, A.D.
Furusawa, K.
Monro, T.M.
Please, C.P.
Richardson, D.J. The mathematical modelling of capillary drawing for holey fibre manufacture. J. Eng. Math. 2002, 43, 201–227.
36. Wu, B.
Zhang, X.
Jeffrey, R.G. A model for downhole fluid and rock temperature prediction during circulation. Geothermics 2014, 50, 202–212.
37. Dirksen, R. Upgrading formation-evaluation electronics for high-temperature drilling environments. J. Pet. Technol. 2011, 63, 24–26.
38. Bullard, E.C. The time necessary for a bore hole to attain temperature equilibrium. Geophys. J. Int. 1947, 5, 127–130.
39. Jang, M.
Chun, T.S.
An, J. The transient thermal disturbance in surrounding formation during drilling circulation. Energies 2022,
15, 8052. [CrossRef]
40. Micallef, D.
van Bussel, G. A Review of urban wind energy research: Aerodynamics and other challenges. Energies 2018, 11, 2204.
41. Santamaría, L.
Vega, M.G.
Pandal, A.
Pérez, J.G.
Velarde-Suárez, S.
Oro, J.M.F. Aerodynamic performance of VAWT airfoils: Comparison between wind tunnel testing using a new three-component strain gauge balance and CFD modelling. Energies 2022, 15, 9351.
42. Torres, J.P.N.
De Jesus, A.S.
Lameirinhas, R.A.M. How to improve an offshore wind station. Energies 2022, 15, 4873.
43. Jaworska-Jozwiak, B.
Dziubinski, M. Effect of deflocculant addition on energy savings in hydrotransport in the lime production process. Energies 2022, 15, 3869.
44. Klein, S.
Dimzon, I.K.
Eubeler, J.
Knepper, T.P. Analysis, occurrence, and degradation of microplastics in the aqueous environment. In Handook of Environmental Chemistry
Springer: Cham, Switzerland, 2018
Volume 58, pp. 51–67.
45. Kevorkijan, L.
Žic, E.
Lešnik, L.
Biluš, I. Settling of mesoplastics in an open-channel flow. Energies 2022, 15, 8786.