Dynamics of Droplets Under Support, Acoustic And/Or Ambient Flow Excitation

Deepu, P

January 2013

The first step on the way to understanding the complicated dynamics of spray is to study the behavior of isolated droplets. In many industrial and natural processes such as turbulent combustion, agricultural sprays, spray cooler, falling raindrops and cloud evolution the droplet is subjected to a chaotic unsteady external flow field. The interaction between the liquid and gaseous phases results in very intricate droplet dynamics like capillary instabilities, atomization, droplet collision and coalescence and vaporization, to name a few. In this dissertation, the focus is on shape oscillations, atomization and vaporization dynamics of pendant and sessile droplets. A droplet residing on a substrate which vibrates vertically at ultrasonic frequency will exhibit different modes of shape oscillation. The competition between capillary forces and inertia forces is basically responsible for these oscillations. However, when an acoustic force field is introduced asymmetrically around the droplet, we discover with the help of ultra high-speed imaging, a new droplet spreading phase. This new method of droplet manipulation could nd application in micro fluidics and lab-on-a-chip systems. By lading the droplet with nanoparticles, the spreading rate can be easily controlled. The spreading phase is followed by an atomization phase where surface ligaments grow to disintegrate into daughter droplets; the intensity of atomization is found to decrease with increase in fluid viscosity. The ability to control atomization characteristics of droplets by lading them with nanoparticles is a powerful technique that may be implemented in spray coolers and combustors to control the spray characteristics or combustion efficiency. Both the spreading and ligament dynamics have been theoretically simulated and the physics behind the observed trends is explained. The growth rate of the ligaments is found to be governed by Weber number modified to include the acoustic pressure level of the standing wave. The frequency of ligament breakup is found to decrease with fluid viscosity and this observation is adequately supported by a theory developed based on the evolution crater on the droplet surface. Turning now to the pendant droplets, by decomposing the droplet shape into Legendre modes, the shape oscillations exhibited by a droplet hanging from the junction of cross-wire placed at the center of an air jet is studied. Both high-speed imaging and hot-wire anemometry are employed. The driving force of oscillation of droplets subjected to the air jet is proved to be the inherent pressure fluctuations in the jet. The effect of surface tension, viscosity and Reynolds number on the shape oscillation level has been examined. The first experimental evidence of viscous attenuation of lower frequencies in a particular mode in glycerol/water mixture is reported. A theoretical model was developed to simulate the droplet shape oscillations induced by different ambient flow fields like pulsatile flow, vortical flow and flow with broadband energy spectrum. The time of interaction of the droplet with an eddy in the flow is found to be very crucial in determining the amplitude of oscillation of the droplet. The shorter the interaction time, the higher are the chances of the droplet oscillation being pushed into resonance. Finally, the heat transfer and droplet regression dynamics of pendant droplets in a hot air stream of various chemical compositions (like conventional fuels, alternative fuels and nanosuspensions) have been experimentally analyzed using high speed imaging. The droplet is deployed at the junction of cross-wire at the centre of a vertical air jet. A hybrid timescale has been proposed which incorporates the effects of latent heat of vaporization, saturation vapor pressure and thermal diffusivity. This timescale in essence encapsulates the different parameters that influence the droplet vaporization rate. The analysis further permitted the evaluation of the effect of various parameters such as surrounding temperature, Reynolds number, far-field vapor presence, impurity content and agglomeration dynamics (nanosuspensions) in the droplet.

Droplets

Droplet Dynamics

Droplet Atomization

Droplet Shape Oscillations

Droplet Vaporization

Droplet Spreading

Sessile Droplets

Pendant Droplets

Droplets - Flow Visualization

Rayleigh Modes

Droplet - Acoustic Field

Excited Droplets

Fluid Dynamics

Contribution à l'étude de l'adhérence des structures du type couche sur substrat par modes de Rayleigh générés et détectés par sources laser / Contribution to the study of the adhesion of layer-on-substrate structures by Rayleigh modes generated and detected by laser sources

Robin, Martin

15 July 2019

La caractérisation non destructive de l’adhérence des structures du type couche sur substrat est un enjeu industriel et académique important. Ce type d’échantillon est en effet utilisé pour de nombreuses applications et sa durée de vie dépend en grande partie de la qualité d’adhérence des films au substrat. Celle-ci modifie sensiblement le comportement dispersif des ondes acoustiques de surface se propageant dans de ce type de structure. Pour générer et détecter ces ondes, un dispositif Ultrasons-Laser a été privilégié. Dans un premier temps, nous avons cherché à contourner les difficultés d’interprétation rencontrées habituellement dans le contrôle de l’adhérence par ondes acoustiques de surface. Les variations d’épaisseur de la couche peuvent en effet avoir une influence sur la dispersion des ondes comparable à celle due à l’adhérence. Pour ce faire, des films polymères dont l’épaisseur est quasi-constante sont employés et apposés sur un substrat en aluminium. Ces films possèdent en plus la propriété d’être transparents. Cela permet de focaliser l’impulsion laser générant les ondes acoustiques à travers le film, directement à la surface du substrat et de placer ainsi la source acoustique à l’interface film-substrat. L’influence de la position de la source sur le comportement dispersif des ondes acoustiques de surface et par conséquent sur le contrôle de la qualité d’adhérence est alors étudiée expérimentalement ainsi qu’au travers de simulations par éléments finis. Finalement, une caractérisation de l’adhérence de différents échantillons est effectuée grâce aux courbes de dispersion obtenues à l’aide de la méthode Matrix-Pencil appliquée aux résultats expérimentaux. En utilisant un algorithme d’inversion, les raideurs d’interface caractéristiques de l’adhérence des échantillons analysés sont estimées. / The non-destructive characterization of the adhesion of layer-on-substrate structures is an important issue in industrial and academic domains. This type of sample is indeed used for many applications and its lifetime depends mainly on the adhesion of the film to the substrate. This one changes significantly the dispersive behavior of the surface acoustic waves. To generate and detect these waves, a Laser-Ultrasonics setup has been used. First, we are looking to bypass the interpretation difficulties usually encountered in the control of adhesion by surface acoustic waves. Indeed, the layer thickness variations influence the dispersion of the waves in a similar way to the adhesion. Consequently, the polymer films used have a quasi-constant thickness and they are deposited directly on an aluminum substrate. In addition, these films are also transparent. It allows us to generate directly the acoustic waves on the substrate surface, at the interface between the film and the substrate, by focusing the laser pulse through the film. In this way, the influence of the source location on the dispersive behavior of the surface acoustic waves and thus on the adhesion quality control may be studied experimentally and by using finite element simulations. Finally, a characterization of the adhesion of several samples is performed using the dispersion curves obtained applying the Matrix-Pencil method to the experimental results. An inversion algorithm allows us to estimate the interfacial stiffnesses corresponding to the adhesion of the samples.

Adhérence

Modes de Rayleigh

Contrôle non destructif

Eléments finis

Pseudo-Distribution de Wigner

Ville lissée

Méthode Matrix Pencil

Adhesion

Rayleigh modes

Ultrasonics

Non-Destructive testing

Finite elements

Smoothed pseudo Wigner

Ville distribution

Matrix Pencil method