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Entropy generation vs energy flow due to natural convection in a trapezoidal cavity with isothermal and non-isothermal hot bottom wall

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  • Basak, Tanmay
  • Anandalakshmi, R.
  • Kumar, Pushpendra
  • Roy, S.

Abstract

A comprehensive understanding of energy flow and entropy generation is needed for an optimal process design via reducing irreversibilities in terms of ‘entropy generation’. In this study, analysis on entropy generation during natural convection in a trapezoidal cavity with various inclination angles (φ = 45°, 60° and 90°) have been carried out for an efficient thermal processing of various fluids of industrial importance (Pr = 0.015, 0.7 and 1000) in the range of Rayleigh number (103 − 105). The total entropy generation (Stotal), average Bejan number (Beav) and average heat transfer rate (Nub¯ and Nul¯) have been computed. The comparison of magnitudes of Sθ and Sψ indicates that maximum entropy generation due to heat transfer (Sθ, max) is identical for both Ra = 103 and Ra = 105 whereas maximum entropy generation due to fluid friction (Sψ, max) is lower for Ra = 103 and that is higher for Ra = 105 due to enhanced fluid flow at higher Ra irrespective of φ and Pr. The total entropy generation (Stotal) is found to increase with Pr due to increase in Sψ with Pr. The non-isothermal heating strategy (case 2) is found to be an energy efficient due to less total entropy generation (Stotal) values despite its lower heat transfer rate (Nub¯) based on lesser heating effect than isothermal heating (case 1) for all φs.

Suggested Citation

  • Basak, Tanmay & Anandalakshmi, R. & Kumar, Pushpendra & Roy, S., 2012. "Entropy generation vs energy flow due to natural convection in a trapezoidal cavity with isothermal and non-isothermal hot bottom wall," Energy, Elsevier, vol. 37(1), pages 514-532.
    • Handle: RePEc:eee:energy:v:37:y:2012:i:1:p:514-532
    DOI: 10.1016/j.energy.2011.11.003
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    2. Mahian, Omid & Mahmud, Shohel & Heris, Saeed Zeinali, 2012. "Analysis of entropy generation between co-rotating cylinders using nanofluids," Energy, Elsevier, vol. 44(1), pages 438-446.
    3. Rashidi, M.M. & Ali, M. & Freidoonimehr, N. & Nazari, F., 2013. "Parametric analysis and optimization of entropy generation in unsteady MHD flow over a stretching rotating disk using artificial neural network and particle swarm optimization algorithm," Energy, Elsevier, vol. 55(C), pages 497-510.
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    5. Saidi, Majid & Karimi, Gholamreza, 2014. "Free convection cooling in modified L-shape enclosures using copper–water nanofluid," Energy, Elsevier, vol. 70(C), pages 251-271.
    6. Akbar, Noreen Sher, 2015. "Entropy generation and energy conversion rate for the peristaltic flow in a tube with magnetic field," Energy, Elsevier, vol. 82(C), pages 23-30.
    7. Selimefendigil, Fatih & Öztop, Hakan F., 2020. "Effects of conductive curved partition and magnetic field on natural convection and entropy generation in an inclined cavity filled with nanofluid," Physica A: Statistical Mechanics and its Applications, Elsevier, vol. 540(C).
    8. Bhardwaj, Saurabh & Dalal, Amaresh & Pati, Sukumar, 2015. "Influence of wavy wall and non-uniform heating on natural convection heat transfer and entropy generation inside porous complex enclosure," Energy, Elsevier, vol. 79(C), pages 467-481.

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