Logarithmic temperature profiles in the bulk of turbulent Rayleigh–Bénard convection for a Prandtl number of 12.3

Wei, Ping; Ahlers, Guenter

doi:10.1017/jfm.2014.560

Cited by 25 publications

(34 citation statements)

References 46 publications

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“…In between exists a wind-sheared region, where the large scale wind shears the boundary layer and the flow is predominantly horizontal close to the plates. The profiles of the mean temperature differ stongly between these regions, which explains the radial dependence of the profiles found in cylindrical experiments [28][29][30]. In these experiments, the amplitude and the quality of the logarithmic fit to the data decreases from the sidewall to the central region of the domain.…”

Section: Impactingmentioning

confidence: 86%

“…Lateral local mean temperature log profiles have been found in experiments and direct numerical simulations (DNS) down to a Rayleigh number of Ra = 10 12 [28][29][30]; a Ra where the BL is expected to more closely resemble a laminar profile instead of a logarithmic (turbulent) profile. The log profiles were found near the sidewall in the experiments and numerics, with the log amplitude and fit quality decreasing towards the center of the cell.…”

Section: Impactingmentioning

confidence: 98%

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Logarithmic Mean Temperature Profiles and Their Connection to Plume Emissions in Turbulent Rayleigh-Bénard Convection

et al. 2015

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Two-dimensional simulations of Rayleigh-Bénard convection at Ra = 5 × 10 10 show that vertical logarithmic mean temperature profiles can be observed in regions of the boundary layer where thermal plumes are emitted. The profile is logarithmic only in these regions and not in the rest of the boundary layer where it is sheared by the large scale wind and impacted by plumes. In addition, the logarithmic behavior is not visible in the horizontal average. The findings reveal that the temperature profiles are strongly connected to thermal plume emission and support a perception that parts of the boundary layer can be turbulent, while others are not. The transition to the ultimate regime, in which the boundary layers are considered to be fully turbulent, can therefore be understood as a gradual increases in fraction of the plume-emitting ('turbulent') regions of the boundary layer.

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Section: Impactingmentioning

confidence: 86%

Section: Impactingmentioning

confidence: 98%

Logarithmic Mean Temperature Profiles and Their Connection to Plume Emissions in Turbulent Rayleigh-Bénard Convection

et al. 2015

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“…This is larger than the increase due to the increase in heating area caused by the roughness (Shen, Tong & Xia 1996;Du & Tong 1998Qiu, Xia & Tong 2005). The result has been extended recently to the case where roughness is added on one plate only (Wei et al 2014).…”

mentioning

confidence: 77%

“…The observation of logarithmic profiles of velocity reported at high Rayleigh numbers in this work is direct evidence of the destabilization of the boundary layers. This is not to be confused with the logarithmic profiles of temperature that have been observed above smooth plates, in both the classical and ultimate states (Ahlers et al 2012a;Ahlers, Bodenschatz & He 2014;Wei & Ahlers 2014), and which do not necessarily imply a transition to turbulent boundary layers.…”

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confidence: 92%

Boundary layer structure in a rough Rayleigh–Bénard cell filled with air

et al. 2015

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In this experimental work, the aim is to understand how turbulent thermal flows are enhanced by the destabilization of the boundary layers. Square-stud roughness elements have been added on the bottom plate of a rectangular Rayleigh-Bénard cell in air, to trigger instabilities in the boundary layers. The top plate is kept smooth. The cell proportions are identical to those of the water cell previously operated and described by Salort et al. (Phys. Fluids, vol. 26, 2014, 015112), but six times larger. The very large size of the Barrel of Ilmenau allows detailed velocity fields to be obtained using particle image velocimetry very close to the roughness elements. We found that the flow is quite different at low Rayleigh numbers, where there is no heat-transfer enhancement, and at high Rayleigh numbers where there is a heat-transfer enhancement due to the roughness. Below the transition, the fluid inside the notch, i.e. between the studs, is essentially at rest, though it is slowly recirculating. The velocity profiles on the top of obstacles and in grooves are fairly compatible with those obtained in the smooth case. Above the transition, on the other hand, we observe large incursions of the bulk inside the notch, and the velocity profiles on the top of obstacles are closer to the logarithmic profiles expected in the case of turbulent boundary layers.

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“…These thermistors were calibrated against the water-bath thermistors. More details about the use and performance of these thermistors are given by He et al (2014) and Wei & Ahlers (2014) and in appendix B. We estimate that the uncertainty of the vertical position of each thermistor is approximately ±0.01L.…”

Section: Temperature Measurementsmentioning

confidence: 99%

Heat-flux enhancement by vapour-bubble nucleation in Rayleigh–Bénard turbulence

et al. 2015

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We report on the enhancement of turbulent convective heat transport due to vapour-bubble nucleation at the bottom plate of a cylindrical Rayleigh-Bénard sample (aspect ratio 1.00, diameter 8.8 cm) filled with liquid. Microcavities acted as nucleation sites, allowing for well-controlled bubble nucleation. Only the central part of the bottom plate with a triangular array of microcavities (etched over an area with diameter of 2.5 cm) was heated. We studied the influence of the cavity density and of the superheat T b − T on (T b is the bottom-plate temperature and T on is the value of T b below which no nucleation occurred). The effective thermal conductivity, as expressed by the Nusselt number Nu, was measured as a function of the superheat by varying T b and keeping a fixed difference T b − T t 16 K (T t is the top-plate temperature). Initially T b was much larger than T on (large superheat), and the cavities vigorously nucleated vapour bubbles, resulting in two-phase flow. Reducing T b in steps until it was below T on resulted in cavity deactivation, i.e. in one-phase flow. Once all cavities were inactive, T b was increased again, but they did not reactivate. This led to one-phase flow for positive superheat. The heat transport of both one-and two-phase flow under nominally the same thermal forcing and degree of superheat was measured. The Nusselt number of the two-phase flow was enhanced relative to the one-phase system by an amount that increased with increasing T b . Varying the cavity density (69, 32, 3.2, 1.2 and 0.3 mm −2 ) had only a small effect on the global Nu enhancement; it was found that Nu per active site decreased as the cavity density increased. The heat-flux enhancement of an isolated nucleating site was found to be limited by the rate at which the cavity could generate bubbles. Local bulk temperatures of one-and two-phase flows were measured at two positions along the vertical centreline. Bubbles increased the liquid temperature (compared to one-phase † Email address for correspondence: daniela.narezo@gmail.com 332 D. Narezo Guzman and others flow) as they rose. The increase was correlated with the heat-flux enhancement. The temperature fluctuations, as well as local thermal gradients, were reduced (relative to one-phase flow) by the vapour bubbles. Blocking the large-scale circulation around the nucleating area, as well as increasing the effective buoyancy of the two-phase flow by thermally isolating the liquid column above the heated area, increased the heat-flux enhancement.

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Logarithmic temperature profiles in the bulk of turbulent Rayleigh–Bénard convection for a Prandtl number of 12.3

Cited by 25 publications

References 46 publications

Logarithmic Mean Temperature Profiles and Their Connection to Plume Emissions in Turbulent Rayleigh-Bénard Convection

Logarithmic Mean Temperature Profiles and Their Connection to Plume Emissions in Turbulent Rayleigh-Bénard Convection

Boundary layer structure in a rough Rayleigh–Bénard cell filled with air

Heat-flux enhancement by vapour-bubble nucleation in Rayleigh–Bénard turbulence

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