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The importance of maldistribution matching for thermal performance of compact heat exchangers

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  • Zhu, Qingzi
  • Pishahang, Mehdi
  • Bichnevicius, Michael
  • Amy, Caleb
  • Caccia, Mario
  • Sandhage, Kenneth H.
  • Henry, Asegun

Abstract

Compact heat exchangers have gained increased attention in recent years, particularly in demanding applications where high temperatures, high pressures, and/or high power densities are required. For decades, the heat exchanger (HX) community believes that flow maldistribution is a key factor for HX effectiveness, that is, reducing the degree of flow maldistribution (MALD) can help increase the HX effectiveness. Therefore, significant efforts have been devoted in the past to optimizing the header geometry to minimize flow maldistribution. This work was initially motivated by this, and the original goal was to figure out a HX header design with the lowest maldistribution. However, by systematically constructing a comprehensive maldistribution matrix, the analysis revealed that the HX effectiveness is not actually determined by the MALD, but instead dominated by the degree of maldistribution mismatch (MISM). This conclusion was also theoretically generalized, which indicated that matching of the local heat capacity rate is key for achieving maximum performance. The MISM provides a local means of tracking this information, while the MALD only provides a global approximation of the maldistribution itself. With this new perspective, flow maldistribution needs not necessarily be avoided, but instead matched between two fluid streams, to improve the HX performance. We demonstrated that by carefully designing the header geometry to match the velocity profiles of the two fluids in a 2 MW PCHE with molten salt and supercritical carbon dioxide (sCO2) as the heat transfer fluids, the HX could achieve a higher effectiveness even when the maldistribution increased. A technoeconomic study using a CSP system as an example revealed that the use of this new HX design paradigm could result in CSP capital cost savings as large as 16.6%.

Suggested Citation

  • Zhu, Qingzi & Pishahang, Mehdi & Bichnevicius, Michael & Amy, Caleb & Caccia, Mario & Sandhage, Kenneth H. & Henry, Asegun, 2022. "The importance of maldistribution matching for thermal performance of compact heat exchangers," Applied Energy, Elsevier, vol. 324(C).
    • Handle: RePEc:eee:appene:v:324:y:2022:i:c:s0306261922008868
    DOI: 10.1016/j.apenergy.2022.119576
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    References listed on IDEAS

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    1. M. Caccia & M. Tabandeh-Khorshid & G. Itskos & A. R. Strayer & A. S. Caldwell & S. Pidaparti & S. Singnisai & A. D. Rohskopf & A. M. Schroeder & D. Jarrahbashi & T. Kang & S. Sahoo & N. R. Kadasala & , 2018. "Ceramic–metal composites for heat exchangers in concentrated solar power plants," Nature, Nature, vol. 562(7727), pages 406-409, October.
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    3. Zhu, Qingzi & Tan, Xu & Barari, Bamdad & Caccia, Mario & Strayer, Alexander R & Pishahang, Mehdi & Sandhage, Kenneth H. & Henry, Asegun, 2021. "Design of a 2 MW ZrC/W-based molten-salt-to-sCO2 PCHE for concentrated solar power," Applied Energy, Elsevier, vol. 300(C).
    4. Pandiyarajan, V. & Chinna Pandian, M. & Malan, E. & Velraj, R. & Seeniraj, R.V., 2011. "Experimental investigation on heat recovery from diesel engine exhaust using finned shell and tube heat exchanger and thermal storage system," Applied Energy, Elsevier, vol. 88(1), pages 77-87, January.
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    1. Zhang, Ji & Hu, Xudong & Wu, Ding & Huang, Xiaohui & Wang, Xuehui & Yang, Yan & Wen, Chuang, 2023. "A comparative study on design and performance evaluation of Organic Rankine Cycle (ORC) under different two-phase heat transfer correlations," Applied Energy, Elsevier, vol. 350(C).
    2. Moojong Kim & Mark Anthony Redo & Jongsoo Jeong & Kiyoshi Saito & Sangmu Lee & Hyunyoung Kim, 2022. "Experimental Investigation of Two-Phase Flow Distribution with Different Vertical Header Configurations," Energies, MDPI, vol. 15(21), pages 1-21, November.

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