Buoyancy Effect on the Flow Pattern and the Thermal Performance of an Array of Circular Cylinders

Fornarelli, Francesco; Lippolis, Antonio; Oresta, Paolo

doi:10.1115/1.4034794

Cited by 18 publications

(13 citation statements)

References 22 publications

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“…investigated the influence of mixed convection on heat transfer around three confined circular cylinders placed in tandem arrangement. Fornarelli et al (2016) tested the effect of aiding and opposing thermal buoyancy on vertical configuration of flow around six circular cylinders placed in-line arrangement.…”

Section: Introductionmentioning

confidence: 99%

Mixed convection heat transfer from a heated circular cylinder

Laidoudi

Bouzit

2019

Bangladesh J. Sci. Ind. Res.

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This paper performs the effects of thermal buoyancy and the triangular arrangement of circular cylinders on fluid flow and heat transfer within a horizontal channel, the governing equations involving continuity; momentum and energy are solved in two-dimensional, laminar and steady flow regime. The average Nusselt number and drag coefficient are computed for the range of these conditions: Ri = 0 to 2 at fixed value of Pr = 1, Reynolds number Re = 30 and geometrical configurations (blockage ratio of β = 0.1). In order to observe the flow structure and temperature field under the gradual effect of thermal buoyancy, the streamlines and isotherm contours are illustrated. It is found that, a gradual increase in the value of buoyancy strength creates an asymmetrical flow around the cylinders. Interesting variations of drag coefficient and average Nusselt number are plotted with respect to Richardson number for each cylinder. Bangladesh J. Sci. Ind. Res.54(1), 83-88, 2019

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Section: Introductionmentioning

confidence: 99%

Mixed convection heat transfer from a heated circular cylinder

Laidoudi

Bouzit

2019

Bangladesh J. Sci. Ind. Res.

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“…The melting/solidification time, temperature time-series in different points, or the dynamic of the melting front are the main results of both numerical simulations [42][43][44] and experiments [45,46]. In some papers [18,45,47,48], snapshots of the simulated velocity field in shell-and-tube configurations are reported. The experiments and numerical results highlight that the melting phase is more affected by the convective motion with respect to the solidification process.…”

Section: Introductionmentioning

confidence: 99%

“…The experiments and numerical results highlight that the melting phase is more affected by the convective motion with respect to the solidification process. Indeed, during the solidification the convective velocity is low and decreases during the process due to the solidification of the PCM [47]. The flow field details help the scientists to explain some convection effects on the heat transfer in the melted PCM.…”

Section: Introductionmentioning

confidence: 99%

Convective Effects in a Latent Heat Thermal Energy Storage

Fornarelli

Camporeale

Fortunato

2019

Heat Transfer Engineering

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Convection within a latent heat thermal energy storage (LHTES) shell-and-tube device filled with phase change material (PCM) has been studied by means of numerical simulations. Both, the heat transfer fluid and the PCM mass, momentum and energy equations are solved and coupled with a conjugate heat transfer model. The study highlights three specific zones within the PCM: the top convective-dominated part, the curvilinear solid-liquid interface, and the bottom conductive-dominated part. The PCM melts from the top to the bottom, therefore the main mechanism of melting appears to be confined in the top part of the solid PCM. However, the flow details reveal a convective cell that includes the whole melted PCM from the top to the bottom of the PCM enclosure. Even though the problem is widely studied by means of experiments and numerical simulations, here the convective flow has been studied quantitatively. During the melting phase the viscous and thermal boundary layers at the walls has been reported at different heights from the bottom of the device. Results show in detail the phenomenology of the melting process within a shelland-tube LHTES supporting the development of design solutions that could enhance the heat transfer of such device.

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“…Crowdy [37] solved the problem of uniform flow past a linear periodic array of cylinders in tandem or crossflow and proposed a quasi-analytical mathematical approach and derived useful approximations for the blockage coefficients between the cylinders. Fornarelli et al [38] studied the effect of buoyancy and spacing between the cylinders on the flow pattern and thermal field in the in-line array of six cylinders at Re = 10 and Pr = 0.7 and Richardson number Ri varying from -1 to 1 and spacing between the cylinders varying from 3.6 to 4D. Their results show that the time-averaged drag coefficient of the array increases linearly for forced convection and aiding buoyancy.…”

Section: Introductionmentioning

confidence: 99%

Analysis of laminar flow across a triangular periodic array of heated cylinders

Asif

Dhiman

2018

J Braz. Soc. Mech. Sci. Eng.

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The laminar flow and heat transfer across a triangular periodic array of heated cylinders are simulated computationally and analyzed. The study has been carried out at Reynolds number 10-100 for fluid volume fraction ranging from 0.7 to 0.99 and Prandtl number ranging from 0.7 to 50. The size of the wake region increases continuously with an increase in the Reynolds number for all values of fluid volume fraction. The recirculation bubble from the rear of a cylinder is reaching the front of the next cylinder in the same column of the periodic array for low values of free volume fraction, but this is not the case with the highest free volume fraction, i.e., 0.99. At high Reynolds number, the flow is separating early on the cylinder surfaces. The wake size at higher Reynolds number 75 and 100 for the lowest free volume fraction 0.7 is more in comparison with the wake size at free volume fraction 0.99, which is explained by plotting the location of flow separation against Reynolds number for both the extreme values of free volume fractions, i.e., 0.7 and 0.99. The isovorticity contours are concentrated in the vicinity of the cylinders on increasing the Reynolds number irrespective of free volume fraction and then convected downstream. On increasing free volume fraction, the friction and pressure drags in the array decrease. The increase in Reynolds number also results in the decrease in the values of the individual (friction and pressure drag coefficients) as well as total drag coefficients for all values of free volume fraction. At high values of Reynolds number, the emergence of carbuncle or thermal spike on isotherm near the cylinder's surface is observed where the value of the local Nusselt number is observed low. The heat transfer improves and the Nusselt number increases as the Reynolds number and/ or Prandtl number increases. On the contrary, heat transfer decreases as free volume fraction increases.

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Buoyancy Effect on the Flow Pattern and the Thermal Performance of an Array of Circular Cylinders

Cited by 18 publications

References 22 publications

Mixed convection heat transfer from a heated circular cylinder

Mixed convection heat transfer from a heated circular cylinder

Convective Effects in a Latent Heat Thermal Energy Storage

Analysis of laminar flow across a triangular periodic array of heated cylinders

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