The mechanism of heat transfer enhancement using longitudinal vortex generators in a laminar channel flow with uniform wall temperature

Zhang, Qiang; Wang, Liang-Bi; Zhang, Yongheng

doi:10.1016/j.ijthermalsci.2017.03.003

Cited by 29 publications

(7 citation statements)

References 46 publications

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“…The

was determined by heat flux

, and heat flux

was determined by velocity, velocity gradient and the combination of velocity and velocity gradient in liquid convective transport. More information can be found in [ 39 ].…”

Section: Resultsmentioning

confidence: 99%

Numerical and Experimental Investigations of Micro Thermal Performance in a Tube with Delta Winglet Pairs

Wang

Zeng

et al. 2021

Micromachines

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In this research, a novel vortex generator (VG) is presented. The experimental and numerical investigations were carried out to study the micro thermal-hydraulic performance in a heated tube. The numerical results showed that the fluid in the core flow region and the near-wall region was fully mixed because of the longitudinal vortices created by the vortex generators. In addition, the experimental results showed that the heat transfer coefficient (h) decreased with the increasing pitch ratio (PR) value, while the friction coefficient exhibited the opposite trend. With the increasing ration angle (RA) numbers, the h values decreased while the f numbers increased. In addition, the maximum and minimum values of the fraction ratio were 1.66 and 4.27, while these values of the Nusselt number ratio were 1.24 and 1.83. The maximum thermal enhancement factor (TEF) was 1.21 when PR = 0.5, RA = 0° and Re = 9090. The heat transfer enhancement mechanism of the vortex generator is explained from the microscopic point of view.

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“…The

was determined by heat flux

, and heat flux

was determined by velocity, velocity gradient and the combination of velocity and velocity gradient in liquid convective transport. More information can be found in [ 39 ].…”

Section: Resultsmentioning

confidence: 99%

Numerical and Experimental Investigations of Micro Thermal Performance in a Tube with Delta Winglet Pairs

Wang

Zeng

et al. 2021

Micromachines

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show abstract

“…However, the authors failed to conclude if swirl flow intensity directly correlates to better heat transfer performances. Furthermore, intense, long-lived swirl flows are difficult to achieve, due to the influence of the constant freestream flow [22]. Thus, in order to produce prominent and prolonged swirling effects, the simultaneous generation and company of vortical structures could potentially strengthen and perpetuate swirl flows, whilst intensifying turbulence.…”

Section: Introductionmentioning

confidence: 99%

Thermohydraulic and Irreversibility Analyses of Swirl Flows Utilizing Distorted Radial Fins: Entropy Generation and Entransy Dissipation Evaluation

Ho,

Tan,

Hung

et al. 2023

International Journal of Energy Research

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The current investigation analyses the convective heat transfer performance, entropy generation, and entransy evaluation of swirl flows generated by distorted radial fins (DRF). As swirl flows and various vortical structures induce large temperature gradients, second law and entransy analyses are necessary to thoroughly evaluate their true thermodynamic influence on heat transfer enhancement. The results indicated that due to the influence of swirl flows and vortices, all angles of the DRF were capable of inducing intense fluid mixing, thinner thermal boundary layers, and turbulent eddies. It was found that overaggressive swirl flows may hinder local heat transfer performances, by enclosing low-velocity heated fluids within the thermal boundary layers. However, as these overaggressive swirl flows and strong vortices propagate downstream, beneficial fluid mixing was eventuated, favouring heat transport over large regions. In terms of thermal performances, the maximum heat transfer enhancement was exhibited by the α=45° DRF, improving the Nusselt numbers up to 59.3%. Accordingly, the highest performance evaluation criterion (PEC) of 1.269 was obtained by the α=45° DRF at the Reynolds number 2389, attributed to the centrifugal effects of the swirl flows. Optimal entropy generation numbers were also exhibited by the α=45° DRF at the highest studied Reynolds number, reducing total entropy generation by 36.81%. Lower entransy thermal resistances were also accredited to greater DRF angles due to the intense swirl effects. In essence, the study concludes that the effects of swirl flows and vortices significantly enhance heat transfer, whilst reducing both entropy generation and entransy dissipation rates, leading to optimal thermal performances.

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“…While passive methods involve the enhancement of surface area for heat exchange, this involves different types of extended surfaces in the form of wavy fins [10], offset fins [11], louvred fins [12][13][14][15][16], sinusoidal plate [17][18][19], dimpled tube [20], etc. Besides these different kinds of tapes [21][22][23][24][25], surface roughness [26,27] and swirl/vortex generators [28][29][30] are also used. While in combined techniques, more than one method of HTE was employed to get a high rate of HT [31][32][33].…”

Section: Introductionmentioning

confidence: 99%

Thermal performance enhancement in heat exchangers using active and passive techniques: a detailed review

Bhattacharyya

Vishwakarma

Srinivasan

et al. 2022

J Therm Anal Calorim

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The mechanism of heat transfer enhancement using longitudinal vortex generators in a laminar channel flow with uniform wall temperature

Cited by 29 publications

References 46 publications

Numerical and Experimental Investigations of Micro Thermal Performance in a Tube with Delta Winglet Pairs

Numerical and Experimental Investigations of Micro Thermal Performance in a Tube with Delta Winglet Pairs

Thermohydraulic and Irreversibility Analyses of Swirl Flows Utilizing Distorted Radial Fins: Entropy Generation and Entransy Dissipation Evaluation

Thermal performance enhancement in heat exchangers using active and passive techniques: a detailed review

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