Experimental Study of an Internally Channeled Tube Heat Exchanger under Turbulent Flow Conditions

•An innovative heat exchanger based on channels-in-tube principle is proposed.•Experimental set-up and procedure to measure pressures and temperatures.•Measured pressure drop and temperature profiles in the exchanger are presented.•A recently proposed CFD model is successfully validated against meas...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2023-11, Vol.214, p.124425, Article 124425
Main Authors: Al-Lami, Abbas J.S., Kenig, Eugeny Y.
Format: Article
Language:English
Subjects:
heat exchanger
heat transfer coefficient
internally channeled tubes
pressure drop
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Summary:•An innovative heat exchanger based on channels-in-tube principle is proposed.•Experimental set-up and procedure to measure pressures and temperatures.•Measured pressure drop and temperature profiles in the exchanger are presented.•A recently proposed CFD model is successfully validated against measured data. In our previous work, an innovative heat exchanger design, the so-called internally channeled tube (ICT), was proposed based on a channels-in-tube principle. The new geometry provides a significantly larger heat transfer area than similar conventional heat exchangers. Furthermore, a three-dimensional numerical model was developed to govern fluid dynamics and heat transfer in the ICT. The focus of the present paper is an experimental investigation of the ICT under turbulent flow conditions. The experimental set-up is presented in detail and the measurement procedure is highlighted. In particular, the maldistribution issue is considered. Measured pressure drop and temperature values are used to validate the numerical model. The deviation between simulated and experimental values is below 6.5% for the pressure drop and below 13% for the heat transfer coefficient.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2023.124425