Technical Hub

Lubricant standards, terminology, and application guidance

Structured technical reference covering lubricant fundamentals, industry standards, specification terminology, and operating considerations for industrial and mobile equipment applications in the United Kingdom and Europe.

Micropitting is a surface-fatigue mechanism affecting rolling and sliding-contact surfaces within enclosed industrial gear systems operating under repeated stress cycles, insufficient lubricant-film thickness, or adverse surface-contact conditions.

Industrial gear-oil viscosity behaviour, EP additive performance, load-carrying capability, operating temperature, gear geometry, and surface finish all influence micropitting risk within heavily loaded enclosed gear drives.

Micropitting mechanism

Micropitting develops through repeated rolling-sliding contact stress acting upon surface asperities under conditions where lubricant-film separation is insufficient to fully isolate mating surfaces.

The resulting surface-fatigue damage commonly appears as fine grey surface distress or matte surface regions across loaded tooth flanks.

Operating conditions influencing micropitting

Micropitting risk commonly increases under:

  • High-contact stress
  • Low-speed high-load operation
  • Insufficient lubricant viscosity
  • Elevated sliding-contact conditions
  • Surface roughness irregularities
  • Shock-loading conditions
  • Lubricant contamination

Lubricant viscosity influence

Industrial gear-oil viscosity directly influences elastohydrodynamic film thickness between loaded gear surfaces.

Insufficient viscosity may reduce lubricant-film separation and increase localised asperity interaction, accelerating micropitting progression under repeated contact stress.

Higher-viscosity industrial gear oils may improve surface separation under heavily loaded and lower-speed operating conditions where permitted by gearbox design.

EP additive performance

Industrial EP gear oils commonly incorporate sulphur-phosphorus additive systems designed to improve surface protection during mixed-film and boundary-lubrication conditions.

Modern industrial gear oils may additionally include performance characteristics developed to support micropitting resistance, FZG load-stage performance, and surface durability within heavily loaded enclosed industrial gear systems.

Surface finish and gear geometry

Gear-surface roughness, manufacturing quality, tooth geometry, and contact alignment significantly influence localised contact stress and lubricant-film behaviour.

Poor alignment, excessive surface roughness, or uneven load distribution may increase surface-fatigue progression.

Contamination influence

Particulate contamination may increase surface distress by introducing abrasive particles into loaded rolling and sliding-contact regions.

Water contamination, oxidation by-products, and lubricant degradation may additionally influence lubricant-film performance and fatigue resistance.

Micropitting evaluation methods

Industrial gear oils may be evaluated using recognised laboratory and OEM micropitting-performance test methods relevant to enclosed industrial gear systems.

Evaluation methods may include:

  • FZG micropitting testing
  • Surface-fatigue analysis
  • OEM gearbox approval testing
  • Load-stage performance evaluation

Reliability considerations

Micropitting control commonly requires coordinated management of:

  • Lubricant viscosity selection
  • EP additive performance
  • Operating temperature
  • Contamination control
  • Gear alignment
  • Lubrication-system condition

Industrial gearbox reliability programmes commonly integrate lubricant-condition monitoring and oil-analysis procedures to identify operating conditions associated with accelerated surface-fatigue progression.

Lubricant Terminology and Standards

Definitions and reference terms used in lubricant documentation, including abbreviations, specification language, performance terminology, and common technical phrases. Designed to support consistent interpretation of technical data sheets and maintenance documentation.

Lubricant Test Methods and Classification Standards

How lubricant properties are measured, classified, and referenced in technical documentation

Hydraulic Systems

Technical guidance for hydraulic oil selection and operation, including viscosity grade selection, temperature and load considerations, filtration and cleanliness, air release and foaming control, water separation, and specification alignment.

Common Hydraulic Oil Grades

Diesel Engine Oil

Reference guide for heavy-duty diesel engine oil viscosity grades and performance categories, including how requirements are written, how to read common specification language, and what to confirm before selecting an oil for fleet service.

Common Diesel Engine OIl Grades

Automotive Gear Oil

Reference guide for automotive gear oil viscosity grades, axle and transmission performance categories, including how specifications are written, how to interpret common approval language, and what to confirm before selecting a lubricant for passenger vehicles, commercial fleets, and severe-duty driveline service.

Common Automotive Gear Oil Grades

Industrial Gear Oil

Technical reference guide for industrial gear oil viscosity grades, EP performance classifications, gearbox operating conditions, contamination control practices, and specification interpretation used across enclosed industrial power transmission systems.

Common Industrial Gear Oil Grades

Technical Transition Guides

Application-focused summaries for reviewing an existing lubricant requirement against a proposed alternative, covering what must match, what can vary, and what should be verified in manufacturer documentation before a change is made.

Applied Lubricant Questions

Question-led technical pages addressing common lubrication decisions encountered in service, maintenance, and specification review.

Hydraulic Oils

Engine Oils

Last reviewed: 1 April 2026
Prepared by the Sinopec Online Technical Team.