Effect of rectangular winglet pair roll angle on the heat transfer enhancement in laminar channel flow

Khanjian, Assadour; Habchi, Charbel; Russeil, S.; Bougeard, D.; Lemenand, Thierry

doi:10.1016/j.ijthermalsci.2016.12.010

Cited by 42 publications

(3 citation statements)

References 21 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…According to their results, a small fin and a large open angle cause a strong flow deflection, resulting in a large share of windows. A numerical investigation on the influence of using rectangular winglet pairs on the thermal performance of a rectangular channel is done by Khanjian et al [111]. Based on the results, it is indicated that the heat transfer improved by increasing the roll angle of vortex generators.…”

Section: Wingletsmentioning

confidence: 99%

A Review of Recent Passive Heat Transfer Enhancement Methods

et al. 2022

View full text Add to dashboard Cite

Improvements in miniaturization and boosting the thermal performance of energy conservation systems call for innovative techniques to enhance heat transfer. Heat transfer enhancement methods have attracted a great deal of attention in the industrial sector due to their ability to provide energy savings, encourage the proper use of energy sources, and increase the economic efficiency of thermal systems. These methods are categorized into active, passive, and compound techniques. This article reviews recent passive heat transfer enhancement techniques, since they are reliable, cost-effective, and they do not require any extra power to promote the energy conversion systems’ thermal efficiency when compared to the active methods. In the passive approaches, various components are applied to the heat transfer/working fluid flow path to improve the heat transfer rate. The passive heat transfer enhancement methods studied in this article include inserts (twisted tapes, conical strips, baffles, winglets), extended surfaces (fins), porous materials, coil/helical/spiral tubes, rough surfaces (corrugated/ribbed surfaces), and nanofluids (mono and hybrid nanofluids).

show abstract

Section: Wingletsmentioning

confidence: 99%

A Review of Recent Passive Heat Transfer Enhancement Methods

et al. 2022

View full text Add to dashboard Cite

show abstract

“…Nonetheless, the secondary flows triggered by longitudinal vortices will disrupt the formation of thermal boundary layers and cause flow instability, which in turn produces turbulence with high scale [7]. In addition, the vortices generated by longitudinal VG (LVG) last a long time until reaching the downstream region [8].…”

Section: Introductionmentioning

confidence: 99%

Effect of Attack Angle of Concave and Convex Winglets Vortex Generators on Thermal-Hydraulic Performance of Fin and Tube Heat Exchangers with Field Synergy Principle

Syaiful¹,

Yunianto²,

Salsabila³

et al. 2021

IJHT

View full text Add to dashboard Cite

In fin and tube heat exchangers, the gas passing through the fin has a lower thermal conductivity than the fluid passing through the tube. The low thermal conductivity brings a high thermal resistance, which suppresses the heat transfer rate. A common practice to enhance fin-side heat transfer is to generate longitudinal vortex by mounting vortex generators (VGs) on the fin. This paper aims to investigate how longitudinal vortex generator (LVG) improves heat transfer and pressure drop. Numerical simulations were carried out to analyze three types of VGs. The installation of VGs was varied with the attack angle changing from 10°, 15°, to 20° with a 1-3-4-7 VG arrangement on the tube. The flow velocity was expressed in Reynolds number (Re) between 364 and 689. The enhancement of heat transfer rate and improvement of pressure drop were analyzed between three types of VG, three different attack angles, and four types of winglet installation, compared to baseline. The simulation results show that the highest convective heat transfer coefficient (84.85%) was achieved by the VG composed of seven concave delta winglet pairs (CDWPs) at the attack angle of 20° and Re = 689; CDWP VG provides the highest heat transfer improvement among all cases.

show abstract

“…Vorticity is an inherent feature of fluid flow and is often considered as an efficient mechanism in the heat and mass transfer phenomena. In many situations of practical interests vorticity is artificially generated to enhance heat and mass transfer [1][2][3][4][5][6][7][8][9][10], but also vorticity exists naturally in many types of fluid flows such as in the near-wall region of turbulent boundary layers [11,12] or surfaces with curvature and/or rotation [13][14][15]. Physical understanding of the mechanism of heat transfer by vorticity is therefore crucial for active and passive control in numerous technological applications [16][17][18][19][20].…”

Section: Introductionmentioning

confidence: 99%

Vorticity and convective heat transfer downstream of a vortex generator

Lemenand

Habchi

Valle

et al. 2018

International Journal of Thermal Sciences

Self Cite

View full text Add to dashboard Cite

Vorticity generation has been identified, since the 80's, as an efficient means for enhancing heat transfer; the mean radial velocity component due to the induced flow pattern contributes to the heat removal. In the present work, momentum and heat transfer are studied in a test section designed to mimic the industrial HEV (High-Efficiency Vorticity) mixer. It consists of a basic configuration with a unique vorticity generator inserted on the bottom wall of a heated straight channel. The aim of this work is to analyze to which extend the convective heat transfer is correlated to the vorticity, as it is presumed to cause the intensification. In this case, the driving vorticity is the streamwise vorticity flux Ω, and the heat transfer is characterized by the Nusselt number Nu, both quantities being spanwise averaged. The study is mainly numerical; we have used the previous PIV measurements and DNS data from the open literature to validate the numerical simulations. It is shown that there exists a strong correlation between the vorticity flux and Nusselt number close to the vortex generator. However, the axial variation diverges for these quantities when moving downstream. The Nusselt number presents a sharp peak over the VG and decreases nearly to its basic level just behind the VG, while the vortex persists far downstream from the tab and relaxes very slowly. Heat transfer intensification at the Nusselt peak is about 100%, and reduces to about 6% downstream of the VG, the intensity of the vorticity momentum being decreased only to about 50% of its peak value at the test section outlet.

show abstract

Effect of rectangular winglet pair roll angle on the heat transfer enhancement in laminar channel flow

Cited by 42 publications

References 21 publications

A Review of Recent Passive Heat Transfer Enhancement Methods

A Review of Recent Passive Heat Transfer Enhancement Methods

Effect of Attack Angle of Concave and Convex Winglets Vortex Generators on Thermal-Hydraulic Performance of Fin and Tube Heat Exchangers with Field Synergy Principle

Vorticity and convective heat transfer downstream of a vortex generator

Contact Info

Product

Resources

About