A Parametric Study into a Passively Enhanced Heat Separation System

Chidiebere Ihekwaba, Mansour Al Qubeissi

    Research output: Chapter in Book/Report/Conference proceedingConference proceedingpeer-review

    Abstract

    In the interest of minimising the amount of work required to enhance thermal separation, a passively induced thermal separation has been investigated. This work is motivated by the recently introduced mechanism of Azanov and Osiptsov. Two methods of reducing the adiabatic wall temperatures have been proposed. First is a modification to the de Laval nozzle from single to dual and triple supersonic nozzles to reduce the degree of aerodynamic heating at the supersonic channel walls. The latter is conducted with a separation to the supersonic flow regime into three parallel interfacing flow sub-regimes. Second is the introduction of water droplets into the supersonic flow channel to absorb the evaporation latent heat equivalent energy. The droplet evaporation has shown a noticeable enhancement in the cooling effects with up to 8 ℃ temperature drops. The model has been compared to the experimental data for compatible results.
    Original languageEnglish
    Title of host publicationAdvances in Heat Transfer and Thermal Engineering
    EditorsC Wen, Y Yan
    PublisherSpringer Nature
    Pages265-269
    Number of pages5
    ISBN (Electronic)978-981-33-4765-6
    ISBN (Print)978-981-33-4764-9
    DOIs
    Publication statusE-pub ahead of print - 2 Jun 2021
    Event16th UK Heat Transfer Conference - East Midlands Conference Centre,University of Nottingham, Nottingham, United Kingdom
    Duration: 8 Sep 201910 Sep 2019
    https://www.nottingham.ac.uk/conference/fac-eng/ukhtc2019/

    Conference

    Conference16th UK Heat Transfer Conference
    Abbreviated titleUKHTC2019
    Country/TerritoryUnited Kingdom
    CityNottingham
    Period8/09/1910/09/19
    Internet address

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