A good lubricant generally possesses the following characteristics: • A high boiling point and low freezing point (in order to stay
liquid within a wide range of temperature) • A high
viscosity index • Thermal stability • Hydraulic stability • Demulsibility • Corrosion prevention • A high resistance to
oxidation • Pour point (the minimum temperature at which oil will flow under prescribed test conditions)
Formulation Typically lubricants contain 90% base oil (most often
petroleum fractions, called
mineral oils) and less than 10%
additives.
Vegetable oils or synthetic liquids such as hydrogenated
polyolefins,
esters,
silicones,
fluorocarbons and many others are sometimes used as base oils. Additives deliver reduced friction and wear, increased
viscosity, improved viscosity index, resistance to
corrosion and
oxidation, aging or contamination, etc. Non-liquid lubricants include powders (dry
graphite,
PTFE,
molybdenum disulphide,
tungsten disulphide, etc.), PTFE tape used in plumbing, air cushion and others.
Dry lubricants such as graphite, molybdenum disulphide and tungsten disulphide also offer lubrication at temperatures (up to 350 °C) higher than liquid and oil-based lubricants are able to operate. Limited interest has been shown in low friction properties of
compacted oxide glaze layers formed at several hundred degrees Celsius in metallic sliding systems; however, practical use is still many years away due to their physically unstable nature.
Additives A large number of additives are used to impart performance characteristics to the lubricants. Modern automotive lubricants contain as many as ten additives, comprising up to 20% of the lubricant, the main families of additives are: •
Extreme pressure (anti-scuffing) additives form protective films on sliding metal parts. These agents are often sulfur compounds, such as dithiophosphates. •
Friction modifiers reduce friction and wear, particularly in the boundary lubrication regime where surfaces come into direct contact. In 1999, an estimated 37,300,000 tons of lubricants were consumed worldwide. Automotive applications dominate, including electric vehicles but other industrial, marine, and metal working applications are also big consumers of lubricants. Although air and other gas-based lubricants are known (e.g., in
fluid bearings), liquid lubricants dominate the market, followed by solid lubricants. Lubricants are generally composed of a majority of base
oil plus a variety of additives to impart desirable characteristics. Although generally lubricants are based on one type of base oil, mixtures of the base oils also are used to meet performance requirements.
Mineral oil The term "
mineral oil" is used to refer to lubricating base oils derived from
crude oil. The
American Petroleum Institute (API) designates several types of lubricant base oil: • Group I – Saturates 0.03%, and
Society of Automotive Engineers (SAE)
viscosity index (VI) of 80 to 120 : Manufactured by solvent extraction, solvent or catalytic dewaxing, and hydro-finishing processes. Common Group I base oil are 150SN (solvent neutral), 500SN, and 150BS (brightstock) • Group II – Saturates > 90% and sulfur 90%, sulfur < 0.03%, and SAE viscosity index over 120 : Manufactured by special processes such as isohydromerization. Can be manufactured from base oil or slax wax from dewaxing process. • Group IV –
Polyalphaolefins (PAO) • Group V – All others not included above, such as naphthenics, polyalkylene glycols (PAG), and
polyesters. The lubricant industry commonly extends this group terminology to include: • Group I+ with a
viscosity index of 103–108 • Group II+ with a viscosity index of 113–119 • Group III+ with a viscosity index of at least 140 Can also be classified into three categories depending on the prevailing compositions: • Paraffinic • Naphthenic • Aromatic
Synthetic oils Petroleum-derived lubricant can also be produced using synthetic hydrocarbons (derived ultimately from petroleum), "
synthetic oils". These include: •
Polyalpha-olefin (PAO) • Synthetic
esters •
Polyalkylene glycols (PAG) •
Phosphate esters •
Perfluoropolyether (PFPE) •
Alkylated naphthalenes (AN) •
Silicate esters •
Ionic fluids •
Multiply alkylated cyclopentanes (MAC)
Solid lubricants PTFE: polytetrafluoroethylene (PTFE) is typically used as a coating layer on, for example, cooking utensils to provide a non-stick surface. Its usable temperature range up to 350 °C and chemical inertness make it a useful additive in special
greases, where it can function both as a thickener and a lubricant. Under extreme pressures, PTFE powder or solids is of little value as it is soft and flows away from the area of contact. Ceramic or metal or alloy lubricants must be used then. By continuous rapid exchange of bound water with other free water molecules, these polymer films keep the surfaces separated while maintaining a high fluidity at the brush–brush interface at high compressions, thus leading to a very low coefficient of friction.
Biolubricant Biolubricants are derived from vegetable oils and other renewable sources. They usually are
triglyceride esters (fats obtained from plants and animals). For lubricant base oil use, the vegetable derived materials are preferred. Common ones include high oleic
canola oil,
castor oil,
palm oil,
sunflower seed oil and
rapeseed oil from vegetable, and
tall oil from tree sources. Many vegetable oils are often hydrolyzed to yield the acids which are subsequently combined selectively to form specialist synthetic esters. Other naturally derived lubricants include
lanolin (wool grease, a natural water repellent).
Whale oil was a historically important lubricant, with some uses up to the latter part of the 20th century as a friction modifier
additive for
automatic transmission fluid. In 2008, the biolubricant market was around 1% of UK lubricant sales in a total lubricant market of 840,000 tonnes/year. , researchers at Australia's
CSIRO have been studying
safflower oil as an engine lubricant, finding superior performance and lower emissions than
petroleum-based lubricants in applications such as
engine-driven
lawn mowers,
chainsaws and other agricultural equipment.
Grain-growers trialling the product have welcomed the innovation, with one describing it as needing very little refining,
biodegradable, a
bioenergy and
biofuel. The scientists have reengineered the plant using
gene silencing, creating a variety that produces up to 93% of oil, the highest currently available from any plant. Researchers at
Montana State University’s Advanced Fuel Centre in the US studying the oil’s performance in a large
diesel engine, comparing it with conventional oil, have described the results as a "game-changer".
Greases Greases are a solid or semi-solid lubricant produced by blending thickening agents within a liquid lubricant. Greases are typically composed of about 80% lubricating oil, around 5% to 10% thickener, and approximately 10% to 15% additives. In most common greases, the thickener is a light or alkali metal soap, forming a sponge-like structure that encapsulates the oil droplets. Beyond lubrication, greases are generally expected to provide corrosion protection, typically achieved through additives. To prevent drying out at higher temperatures, dry lubricants are also added. By selecting appropriate oils, thickeners, and additives, the properties of greases can be optimized for a wide range of applications. There are greases suited for high or extremely low temperatures, vacuum applications, water-resistant and weatherproof greases, highly pressure-resistant or creeping types, food-grade, or exceptionally adhesive greases.
Radiation effects Evidence of lubricants under ionizing radiation is limited and outdated. Radiolysis can degrade or improve properties, and reviews recommend standardized comparative testing. == Functions ==