Rayleigh Bénard convective instability of a fluid under high-frequency vibration

Cissé, Issa; Bardan, Gérald; Mojtabi, Abdelkader

doi:10.1016/j.ijheatmasstransfer.2004.05.002

Cited by 33 publications

(11 citation statements)

References 15 publications

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“…On the other hand, under normal gravity conditions, Gershuni et al (24) theoretically analyzed the linear stability of double diffusive convection in the presence of high-frequency vibration and determined the conditions of quasi-equilibrium. It was further found that vibration can generate or delay convective instabilities depending on the mutual orientation of the vibration axis and gravity (25,26). Specifically, vertical vibration that is parallel to the gravity has been used to stabilize the unstable thermal gradients (27), even in the turbulent regime (28,29).…”

Section: Introductionmentioning

confidence: 99%

Vibration-induced boundary-layer destabilization achieves massive heat-transport enhancement

2020

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Thermal turbulence is well known as a potent means to convey heat across space by a moving fluid. The existence of the boundary layers near the plates, however, bottlenecks its heat-exchange capability. Here, we conceptualize a mechanism of thermal vibrational turbulence that breaks through the boundary-layer limitation and achieves massive heat-transport enhancement. When horizontal vibration is applied to the convection cell, a strong shear is induced to the body of fluid near the conducting plates, which destabilizes thermal boundary layers, vigorously triggers the eruptions of thermal plumes, and leads to a heat-transport enhancement by up to 600%. We further reveal that such a vibration-induced shear can very efficiently disrupt the boundary layers. The present findings open a new avenue for research into heat transport and will also bring profound changes in many industrial applications where thermal flux through a fluid is involved and the mechanical vibration is usually inevitable.

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Section: Introductionmentioning

confidence: 99%

Vibration-induced boundary-layer destabilization achieves massive heat-transport enhancement

2020

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“…The fundamental treatise [1] comprises a systematic study of convective flows induced by high and finite frequency vibrations in closed and infinite cavities. Thermovibrational convection in square, rectangular, and cubic cavities was widely investigated providing a variety of mean flow structures and bifurcation scenarios [5][6][7][8]. Influence of vibration on double diffusive convection with the Soret effect was analyzed in [9].…”

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confidence: 99%

Experimental Evidence of Thermal Vibrational Convection in a Nonuniformly Heated Fluid in a Reduced Gravity Environment

et al. 2008

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We report experimental evidence of convection caused by translational vibration of nonuniformly heated fluid in low gravity. The theory of vibrational convection in weightlessness is well developed but direct experimental proof has been missing. An innovative point of the experiment is the observation of a temperature field in the front and side views of the cubic cell. In addition, particle tracing is employed. The evolution of this field is studied systematically in a wide range of frequencies and amplitudes. The flow structures reported in previous numerical studies are confirmed. The transition from four-vortex flow to the pattern with three vortices is observed in the transient state.

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“…Secondary forcing can also be used delay or manipulate the Rayleigh-Bénard instability. As with the Rayleigh-Taylor instability, high frequency vertical vibrations (in this case, parallel to the temperature gradient) can suppress convection [30,61,160] as can modulation of the applied temperatures [31] or the addition of an oscillatory shear flow [76]. Closed-loop (feedback) control strategies have been investigated, with many based on the application of inhomogeneous perturbations to the heat flux at the lower boundary [67,116].…”

Section: Strategies For Controlmentioning

confidence: 99%

A review of fluid instabilities and control strategies with applications in microgravity

Porter

Sánchez

Shevtsova

et al. 2021

Math. Model. Nat. Phenom.

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We give a brief review of several prominent fluid instabilities representing transitions driven by gravity, surface tension, thermal energy, and applied motion/acceleration. Strategies for controlling these instabilities, including their pattern formation properties, are discussed. The importance of gravity for many common fluid instabilities is emphasized and used to understand the sometimes dramatically different behavior of fluids in microgravity environments. This is illustrated in greater detail, using recent results, for the case of the frozen wave instability, which leads to large columnar structures in the absence of gravity. The development of these highly nonlinear states is often complex, but can be manipulated through an appropriate choice of forcing amplitude, container length and height, initial inclination of the surface, and other parameters affecting the nonlinear and inhomogeneous growth process. The increased opportunity for controlling fluids and their instabilities via small forcing or parameter changes in microgravity is notable.

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Rayleigh Bénard convective instability of a fluid under high-frequency vibration

Cited by 33 publications

References 15 publications

Vibration-induced boundary-layer destabilization achieves massive heat-transport enhancement

Vibration-induced boundary-layer destabilization achieves massive heat-transport enhancement

Experimental Evidence of Thermal Vibrational Convection in a Nonuniformly Heated Fluid in a Reduced Gravity Environment

A review of fluid instabilities and control strategies with applications in microgravity

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