Tribology is the science of the mechanisms of Friction,
Lubrication, and Wear of interacting surfaces that are in relative motion.
A Tribological System (Tribosystem) transform Inputs as a type of motion, the sequence of motion, load, velocities, temperatures, and loading time; by Disturbance Variables as material and geometry properties and interactions between elements; in Outputs as force, torque, speed, motion, mechanical energy, material variables, and signal variables; and Loss Variables as friction and wear.
Friction is
the resistance to movement of one body over body, the friction laws were
formulated by Guillaume Amontons:
1st Law: Friction force is proportional
to the applied load.
2nd Law: Friction force is independent
of the apparent contact area.
3rd Law (also Coulomb's Law): Friction
is independent of sliding velocity.
Generally, friction force F is the
result to multiply the normal load N by the coefficient of friction m. The static coefficient of friction may be
greater than the kinetic coefficient of friction.
The microscopic mechanics that are
involved in generating friction are:
1. Adhesion.
2. Mechanical interactions
of surface asperities.
3. Plowing of one
surface by asperities on the other.
4. Deformation and/or
fracture of surface layers.
5. Interference and local plastic
deformation caused by third bodies primarily agglomerated wear particles
trapped between the moving surfaces.
Wear is the succession of events whereby atoms, products of chemical
conversion, fragments, et al., are induced to leave the system.
The major wear modes are:
· Abrasive Wear: occurs whenever a solid object is loaded against particles of a
material that has an equal or greater hardness.
· Adhesive Wear: Cold-welding describes the
formation of small connections whereby tiny disruptions arise during translation.
· Corrosive & Oxidative Wear: Chemical the reaction between the worm material and a corroding medium can be a chemical
reagent, reactive lubricant, or even air.
· Fatigue Wear: By deformations sustained by the
asperities and surfaces make contact. They are accompanied by very high local
stresses that are repeated a large number of times.
· Erosive Wear: By the impact of particles of
solid or liquid against the surface of an object.
· Electrical Erosion Wear: Occurs when
electric current passes between two metal surfaces through the oil or grease
film.
· Fretting Wear: Occurs whenever short amplitude
reciprocating sliding between contacting surfaces is sustained for a large number
of cycles. If micro-particles are present then the name is Polishing Wear.
· Cavitation Wear: By the cyclic formation and the collapse of bubbles on a solid surface in contact with a fluid.
Lubrication is
the process or technique employed to reduce friction between, and wear of one
or both, surfaces in proximity and moving relative to each other, by
interposing a substance called a Lubricant in between them.
The main property of a lubricant is Viscosity that is defined as the internal
resistance to flow of one layer of the fluid, moving in relation to an adjacent
layer; Absolute Viscosity or Dynamic Viscosity (h) is the proportional factor of
the shear stress in a fluid to the rate of change of velocity with respect the the thickness of the fluid film. Kinematic Viscosity (u) is the ratio of the dynamic viscosity
to the density of the fluid.
Stribeck Curve, defined by Richard Stribeck, is basically a curve between Coefficient
of Friction and a number defined as dynamic viscosity with relative sliding
velocity per unit load. The curve defines four different forms of lubrication
called the Lubrication Regimes.
a. Boundary
Lubrication. The condition when the fluid films are negligible and
there is considerable asperity contact. The mean film thickness is lower than
the surface roughness; the coefficient of friction is a maximum in this
area.
b. Mixed
Lubrication. The number is higher, the mean film thickness is just
higher than surface roughness, so the tallest asperities of the bounding
surfaces will protrude through the film and occasionally come in contact. The
coefficient of friction reduces dramatically until a minimum.
c. Elastohydrodynamic
Lubrication (EHL). The condition
that occurs when a lubricant is introduced between surfaces that are in rolling
contacts, such as ball and rolling element bearings. In this lubrication regime,
the load is sufficiently high enough to produce Hertzian pressures for the surfaces
to elastically deform, in those points, the lubricant film has got a
Non-Newtonian behavior. The coefficient of friction is minimum in this area; the behavior
is defined by the Cheng equation.
d. Hydrodynamic
Lubrication. The condition when the load-carrying surfaces are
separated by a relatively thick film of lubricant. This is a stable regime of
lubrication and metal-to-metal contact does not occur during the steady-state
operation of the bearing. The lubricant pressure is self-generated by the
moving surfaces drawing the lubricant into the wedge formed by the bounding
surfaces at a high enough velocity to generate the pressure to completely
separate the surfaces and support the applied load. The coefficient of friction
increase in this area, the behavior is defined by the Reynolds equation.
Also the Hydrostatic Lubrication regime can be added, in which surfaces are fully separated by a lubricating film of liquid or gas forced between the surfaces by external pressure.
