Performance enhancement of fin and tube heat exchanger employing curved delta winglet vortex generator with circular punched holes
2023 (English)In: International Journal of Thermofluids, E-ISSN 2666-2027, Vol. 20, article id 100452Article in journal (Refereed) Published
Abstract [en]
The generation of vortices has recently gained attention as a potential passive technique for improving air-side heat transfer in a fin and tube heat exchanger. This study proposes novel configurations of a curved delta winglet vortex generator (CDWVG) with and without circular holes to improve heat transfer in FTHEs. The present study utilizes a three-dimensional numerical analysis to investigate the thermal-hydraulic performance analysis of fin and tube heat exchanger (FTHE) with curved delta winglet vortex generators (CDWVG) with or without circular holes, operating across a wide Reynolds number range (i.e., from 400 to 2000). In addition to being arranged in vertical and horizontal configurations, the CDWVGs are oriented in the same way as the flow direction. Therefore, the pressure distribution, temperature distribution, and flow structure distribution of an FTHE with a four-in-line circular tube configuration are analyzed and compared between FTHE without vortex generator (VG) and five different configurations of CDWVG (i.e., CDWVG without hole, CDWVG with 1 hole, CDWVG with 2 holes, CDWVG with 3 holes and CDWVG with 6 holes). The pressure drop (ΔP), London area goodness factor (LAGF) (j/f), Nusselt number (Nu), and Colburn factor (j) are also used to evaluate the thermo-hydraulic performance of FTHE. The FHTE performance with CDWVGs can be affected by the number of punched holes, which is evaluated using a dimensionless number including Performance Evaluation Criteria (PEC), Colburn factor, etc. The thermo-hydraulic efficiency of the FTHE is improved significantly by using CDWVGs with circular punched holes. Nusselt number decreases across all the VG configurations (i.e., CDWVG without hole, CDWVG with 1 hole, CDWVG with 2 holes, CDWVG with 3 holes, and CDWVG with 6 holes) due to the lower flow resistance. Compared to other CDWVG configurations, the 6-hole configuration of CDWVG is the most effective. The Nusselt number of CDWVG with 6 holes increases by 77.25% and 42.51% at Reynolds numbers of 400 and 2000, with respect to fin and tube heat exchangers without vortex generator, respectively. On the other hand, friction is decreased by 5.11%. Therefore, when considering the London area goodness factor, CDWVG with six holes is found to be superior to other CDWVG configurations. © 2023 The Authors
Place, publisher, year, edition, pages
Elsevier B.V. , 2023. Vol. 20, article id 100452
Keywords [en]
Curved delta winglet vortex generator, Fin and tube heat exchanger, London area goodness factor, Vortex generator with circular holes, Delta wing aircraft, Efficiency, Fins (heat exchange), Pressure drop, Reynolds number, Tubes (components), Vortex flow, Vorticity, Wings, Circular holes, Colburn factors, Delta winglets, Reynold number, Vortex generator with circular hole, Vortex generators, Nusselt number
National Category
Energy Engineering
Identifiers
URN: urn:nbn:se:du-46934DOI: 10.1016/j.ijft.2023.100452Scopus ID: 2-s2.0-85169786087OAI: oai:DiVA.org:du-46934DiVA, id: diva2:1796298
2023-09-122023-09-122025-10-09