Non-isolated drop impact on surfaces

Upon impact on a solid surface, a drop expands into a sheet, a corona, which can rebound, stick or splash and fragment into secondary droplets. Previously, focus has been placed on impacts of single drops on surfaces to understand their splash, rebound or spreading. This is important for spraying, printing, and environmental and health processes such as contamination by pathogen-bearing droplets. However, sessile drops are ubiquitous on most surfaces and their interaction with the impacting drop is largely unknown. We report on the regimes of interactions between an impacting drop and a sessile drop. Combining experiments and theory, we derive the existence conditions for the four regimes of drop–drop interaction identified, and report that a subtle combination of geometry and momentum transfer determines a critical impact force governing their physics. Crescent-moon fragmentation is most efficient at producing and projecting secondary droplets, even when the impacting drop Weber number would not allow for splash to occur on the surface considered if the drop were isolated. We introduce a critical horizontal impact Weber number $We_{c}$ that governs the formation of a sheet from the sessile drop upon collision with the expanding corona of the impacting drop. We also predict and validate important properties of the crescent-moon fragmentation: the extension of its sheet base and the ligaments surrounding its base. Finally, our results suggest a new paradigm: impacts on most surfaces can make a splash of a new kind – a crescent-moon – for any impact velocity when neighbouring sessile drops are present.

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An Experimental Study on the Oblique Collisions of Water Droplets With a Smooth Hot Solid

Journal of Fluids Engineering ◽

10.1115/1.4006926 ◽

2012 ◽

Vol 134 (7) ◽

Cited By ~ 3

Author(s):

Hitoshi Fujimoto ◽

Ryota Doi ◽

Hirohiko Takuda

Keyword(s):

Surface Temperature ◽

Impact Velocity ◽

Solid Surface ◽

Impact Angle ◽

Alloy Surface ◽

Inconel 625 ◽

Normal Velocity ◽

Inconel 625 Alloy ◽

Secondary Droplets ◽

The Impact

The motions of liquid droplets impinging on a solid substrate have been studied experimentally in fundamental research on various types of industrial applications, including spray cooling. The oblique collision of a single water droplet with a hot Inconel 625 alloy surface has been investigated by means of a two-directional flash photography technique that uses two digital still cameras and three flash units. The experiments were conducted under the following conditions. The preimpact diameter of the droplets was approximately 0.6 mm, the impact velocity was 1.9–3.1 m/s, and the temperature of the Inconel 625 alloy surface ranged from 170 °C to 500 °C. The impact angle of droplets on the solid surface was in the range 45 deg–90 deg. Experiments using 2.5 mm diameter droplets at an impact velocity of 0.84–1.4 m/s were also conducted at the surface temperature of 500 °C. At surface temperatures of 200 °C, 300 °C, and 400 °C, the droplet deforms into an asymmetric shape and moves downward along the tilted surface. Numerous secondary droplets jet upward from the deforming droplet as a result of the blowout of vapor bubbles into the atmosphere. At a surface temperature of 500 °C and a low Weber number Wen based on the normal velocity component to the solid surface, no secondary droplets are observed. The droplet rebounds off the solid without disintegrating. The droplet becomes almost axisymmetric in shape during the collision regardless of the impact angle. The dimensionless collision behaviors of large and small droplets were similar for the same Wen when the temperature was 500 °C. Using Wen, we investigated the deformation characteristics of droplets in oblique collisions.

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Air mediates the impact of a compliant hemisphere on a rigid smooth surface

Soft Matter ◽

10.1039/d0sm02163f ◽

2021 ◽

Author(s):

Siqi Zheng ◽

Sam Dillavou ◽

John M. Kolinski

Keyword(s):

Elastic Body ◽

Elastic Properties ◽

Impact Velocity ◽

Solid Surface ◽

High Speed ◽

Smooth Surface ◽

High Speed Imaging ◽

The Impact ◽

Rigid Smooth

When a soft elastic body impacts upon a smooth solid surface, the intervening air fails to drain, deforming the impactor. High-speed imaging with the VFT reveal rich dynamics and sensitivity to the impactor's elastic properties and the impact velocity.

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Dynamics of Liquid Sheet Breakup in Splash Plate Atomization

Journal of Fluids Engineering ◽

10.1115/1.4037676 ◽

2017 ◽

Vol 140 (1) ◽

Cited By ~ 3

Author(s):

G. Thunivumani ◽

Hrishikesh Gadgil

Keyword(s):

Solid Surface ◽

Weber Number ◽

Jet Impingement ◽

Liquid Sheet ◽

Force Balance ◽

Impingement Angle ◽

Wide Range ◽

Perforated Sheet ◽

Sheet Breakup ◽

Regime Map

An experimental study was conducted to investigate the breakup of a liquid sheet produced by oblique impingement of a liquid jet on a plane solid surface. Experiments are carried out over a wide range of jet Weber number (80–6300) and various jet impingement angles (30 deg, 45 deg, and 60 deg) are employed to study the sheet dynamics. The breakup of a liquid sheet takes place in three modes, closed rim, open rim, and perforated sheet, depending upon the Weber number. The transitions across the modes are also influenced by the impingement angle with the transition Weber number reducing with increase in impingement angle. A modified regime map is proposed to illustrate the role of impingement angle in breakup transitions. A theoretical model based on force balance at the sheet edge is developed to predict the sheet parameters by taking the shear interaction between the sheet and the solid surface into account. The sheet shape predicted by the model fairly matches with the experimentally measured sheet shape. The breakup length and width of the sheet are measured and comparisons with the model predictions show good agreement in closed rim mode of breakup.

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Lifting a sessile oil drop from a superamphiphobic surface with an impacting one

Science Advances ◽

10.1126/sciadv.aba4330 ◽

2020 ◽

Vol 6 (34) ◽

pp. eaba4330

Author(s):

Olinka Ramírez-Soto ◽

Vatsal Sanjay ◽

Detlef Lohse ◽

Jonathan T. Pham ◽

Doris Vollmer

Keyword(s):

Surface Tension ◽

Energy Transfer ◽

Impact Velocity ◽

Sessile Drop ◽

Cloud Formation ◽

Impact Dynamics ◽

Combustion Engines ◽

Intrinsic Properties ◽

Natural Processes ◽

The Impact

Colliding drops are encountered in everyday technologies and natural processes, from combustion engines and commodity sprays to raindrops and cloud formation. The outcome of a collision depends on many factors, including the impact velocity and the degree of alignment, and intrinsic properties like surface tension. Yet, little is known on binary impact dynamics of low-surface-tension drops on a low-wetting surface. We investigate the dynamics of an oil drop impacting an identical sessile drop sitting on a superamphiphobic surface. We observe five rebound scenarios, four of which do not involve coalescence. We describe two previously unexplored cases for sessile drop liftoff, resulting from drop-on-drop impact. Numerical simulations quantitatively reproduce the rebound scenarios and enable quantification of velocity profiles, energy transfer, and viscous dissipation. Our results illustrate how varying the offset from head-on alignment and the impact velocity results in controllable rebound dynamics for oil drop collisions on superamphiphobic surfaces.

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The shape evolution of liquid droplets in miscible environments

Journal of Fluid Mechanics ◽

10.1017/jfm.2018.535 ◽

2018 ◽

Vol 852 ◽

pp. 422-452 ◽

Cited By ~ 2

Author(s):

Daniel J. Walls ◽

Eckart Meiburg ◽

Gerald G. Fuller

Keyword(s):

Sessile Drop ◽

Liquid Droplet ◽

Leading Edge ◽

Numerical Approach ◽

Shape Evolution ◽

Liquid Droplets ◽

Miscible Liquids ◽

Experimental Findings ◽

Sessile Drops ◽

Pendant Drops

Miscible liquids often come into contact with one another in natural and technological situations, commonly as a drop of one liquid present in a second, miscible liquid. The shape of a liquid droplet present in a miscible environment evolves spontaneously in time, in a distinctly different fashion than drops present in immiscible environments, which have been reported previously. We consider drops of two classical types, pendant and sessile, in building upon our prior work with miscible systems. Here we present experimental findings of the shape evolution of pendant drops along with an expanded study of the spreading of sessile drops in miscible environments. We develop scalings considering the diffusion of mass to group volumetric data of the evolving pendant drops and the diffusion of momentum to group leading-edge radial data of the spreading sessile drops. These treatments are effective in obtaining single responses for the measurements of each type of droplet, where the volume of a pendant drop diminishes exponentially in time and the leading-edge radius of a sessile drop grows following a power law of $t^{1/2}$ at long times. A complementary numerical approach to compute the concentration and velocity fields of these systems using a simplified set of governing equations is paired with our experimental findings.

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Numerical modelling of destruction of a drop of non-Newtonian fluid in a gas flow

EPJ Web of Conferences ◽

10.1051/epjconf/201919600042 ◽

2019 ◽

Vol 196 ◽

pp. 00042

Author(s):

Anna Shebeleva ◽

Andrey Minakov ◽

Alexander Lobasov ◽

Alexander Shebelev

Keyword(s):

Weber Number ◽

Gas Flow ◽

Filter Cake ◽

Droplet Breakup ◽

Secondary Droplet ◽

Large Solution ◽

Secondary Droplets ◽

Secondary Breakup ◽

Les Model ◽

Good Agreement

The research presents the numerical modeling findings of the secondary breakup of droplets of coal water slurries containing petrochemicals (CWSP) droplet with the filter cake content of 50 % for different Weber number values. The modeling method of the secondary droplet breakup is based on the VOF method for interface resolution, LES model for describing turbulence, and the technology of adapted dynamic grids. This technology enables the grid to be automatically concentrated in the region of large solution gradients during the calculation. The implementation of such a highly detailed grid allowed resolving secondary droplets with the dimensions down to 15 μm. We established the droplet breakup modes depending on the Weber number ranging from 36 to 342. The structure of the stream behind droplets was studied in detail and the numerical method was tested. The results are in good agreement with the results of known experiments.

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Study on Corner Contact Shock of Gear Transmission by ADAMS Software

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.778.205 ◽

2015 ◽

Vol 778 ◽

pp. 205-211

Author(s):

Li He ◽

Jin Yuan Tang

Keyword(s):

Penetration Depth ◽

Impact Velocity ◽

Impact Force ◽

Ansys Software ◽

New Approach ◽

Adams Software ◽

Simulation Results ◽

The Impact ◽

The Relationship ◽

Key Parameter

Solving gear meshing impact force problems by using ADAMS software is studied.A pair of tooth meshing model is established based on UG, modal neutral file is generated by using ANSYS software, calculating gear meshing impact after Importing ADAMS. The relationship between the impact velocity and the impact force by taking reasonable key parameter about penetration depth in ADAMS simulation.A new approach for studying gear meshing impact is proposed here, and the simulation results show that ADAMS software is a very useful tool for solving gear corner contact shock problems outside the normal path of action line.

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