Thin fluid film with particles flowing down an inclined plane

In fluid dynamics, lubrication theory describes the flow of fluids (liquids or gases) in a geometry in which one dimension is significantly smaller than the others. An example is the flow above

air hockey Air hockey is a ''Pong''-like tabletop sport where two opposing players try to score goals against each other on a low-friction table using two hand-held discs ("mallets") and a lightweight plastic puck. The air hockey table has raised edges ...

tables, where the thickness of the air layer beneath the puck is much smaller than the dimensions of the puck itself. Internal flows are those where the fluid is fully bounded. Internal flow lubrication theory has many industrial applications because of its role in the design of

fluid bearing Fluid bearings are bearings in which the load is supported by a thin layer of rapidly moving pressurized liquid or gas between the bearing surfaces. Since there is no contact between the moving parts, there is no sliding friction, allowing flu ...

s. Here a key goal of lubrication theory is to determine the pressure distribution in the fluid volume, and hence the forces on the bearing components. The working fluid in this case is often termed a lubricant. Free film lubrication theory is concerned with the case in which one of the surfaces containing the fluid is a free surface. In that case the position of the free surface is itself unknown, and one goal of lubrication theory is then to determine this. Examples include the flow of a viscous fluid over an inclined plane or over topography. Surface tension may be significant, or even dominant. Issues of wetting and

dewetting In fluid mechanics, dewetting is one of the processes that can occur at a solid–liquid, solid–solid or liquid–liquid interface. Generally, dewetting describes the process of retraction of a fluid from a non-wettable surface it was forced t ...

then arise. For very thin films (thickness less than one

micrometre The micrometre ( international spelling as used by the International Bureau of Weights and Measures; SI symbol: μm) or micrometer (American spelling), also commonly known as a micron, is a unit of length in the International System of Unit ...

), additional intermolecular forces, such as

Van der Waals force In molecular physics, the van der Waals force is a distance-dependent interaction between atoms or molecules. Unlike ionic or covalent bonds, these attractions do not result from a chemical electronic bond; they are comparatively weak and th ...

s or disjoining forces, may become significant.

Theoretical basis

Mathematically, lubrication theory can be seen as exploiting the disparity between two length scales. The first is the characteristic film thickness,

H

, and the second is a characteristic substrate length scale

L

. The key requirement for lubrication theory is that the ratio

\varepsilon = H/L

is small, that is,

\epsilon  \ll 1

. The

Navier–Stokes equations In physics, the Navier–Stokes equations ( ) are partial differential equations which describe the motion of viscous fluid substances, named after French engineer and physicist Claude-Louis Navier and Anglo-Irish physicist and mathematician Geo ...

(or Stokes equations, when fluid inertia may be neglected) are expanded in this small parameter, and the leading-order equations are then :

\frac & = \mu\frac \end

where

x

and

z

are coordinates in the direction of the substrate and perpendicular to it respectively. Here

p

is the fluid pressure, and

u

is the fluid velocity component parallel to the substrate;

\mu

is the fluid viscosity. The equations show, for example, that pressure variations across the gap are small, and that those along the gap are proportional to the fluid viscosity. A more general formulation of the lubrication approximation would include a third dimension, and the resulting differential equation is known as the

Reynolds equation The Reynolds Equation is a partial differential equation governing the pressure distribution of thin viscous fluid films in lubrication theory. It should not be confused with Osborne Reynolds' other namesakes, Reynolds number and Reynolds-averaged N ...

. Further details can be found in the literatureOron, A; Davis S. H., and S. G. Bankoff,
Long-scale evolution of thin liquid films
, Rev. Mod. Phys. 69, 931–980 (1997) or in the textbooks given in the bibliography.

Applications

An important application area is lubrication of machinery components such as

s and mechanical seals.

Coating A coating is a covering that is applied to the surface of an object, usually referred to as the substrate. The purpose of applying the coating may be decorative, functional, or both. Coatings may be applied as liquids, gases or solids e.g. Pow ...

is another major application area including the preparation of

thin films A thin film is a layer of material ranging from fractions of a nanometer ( monolayer) to several micrometers in thickness. The controlled synthesis of materials as thin films (a process referred to as deposition) is a fundamental step in many ...

printing Printing is a process for mass reproducing text and images using a master form or template. The earliest non-paper products involving printing include cylinder seals and objects such as the Cyrus Cylinder and the Cylinders of Nabonidus. The ...

painting Painting is the practice of applying paint, pigment, color or other medium to a solid surface (called the "matrix" or "support"). The medium is commonly applied to the base with a brush, but other implements, such as knives, sponges, and ai ...

and adhesives. Biological applications have included studies of red blood cells in narrow capillaries and of liquid flow in the lung and eye.

Notes

References

*Aksel, N.; Schörner M. (2018), ''Films over topography: from creeping flow to linear stability, theory, and experiments, a review'', Acta Mech. 229, 1453–1482. oi:10.1007/s00707-018- 2146-y*Batchelor, G. K. (1976), ''An introduction to fluid mechanics'', Cambridge University Press. . *Hinton E. M.; Hogg A. J.; Huppert H. E.; (2019), ''Interaction of viscous free-surface flows with topography'' J. Fluid Mech. 876, 912–938. oi:10.1017/jfm.2019.588*Lister J. R. (1992) ''Viscous flows down an inclined plane from point and line sources'' J. Fluid Mech. 242, 631–653. oi:10.1017/S0022112092002520*Panton, R. L. (2005), ''Incompressible Flow'' (3rd ed.), New York: Wiley. {{ISBN, 978-0-471-26122-3. *San Andres, L., ''MEEN334 Mechanical Systems Course Notes''

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