[ Conventional]
energies

[ Optimal ] state

Track the pattern of wear to ensure the lubricant is in optimal state at all times.

Gas engines

Benefits
  • Keep track of the level of oil degradation.
  • Measure the relationship between lubricant degradation and gas quality, combining the engine’s hours in operation and the level of contaminants in the oil.
  • Measure patterns of wear in the main engine components.
  • Measure engine performance and mechanical tension during transitory conditions.
  • This solution can be linked to measurements based on NIR technology (TBN, TAN, soot, insoluble content) to give a complete
  • overview of engine state and oil quality.

Gas turbines

Benefits
  • Monitor information on patterns of wear in turbine bearings.
  • Provide control of the risk of varnish formation.
  • Provide control over the useful life of generator bearings.
  • Control new lubricant quality before it is supplied to the turbine.
  • Comprehensively control the lubricant life-cycle and optimise changes without compromising lubrication system effectiveness.

Steam turbines

Benefits
  • Monitor information on patterns of wear in turbine bearings.
  • Allow measurement of lubricant contamination by water content.
  • Control new lubricant quality before it is supplied to the turbine.
  • Comprehensively control the lubricant life-cycle and optimise changes without compromising lubrication system effectiveness.

Hydraulic turbines

Benefits
  • Monitor information on patterns of wear in turbine bearings
  • Provide control of the risk of varnish formation
  • Provide control over the useful life of generator bearings
  • Control new lubricant quality before it is supplied to the turbine
  • Comprehensively control the lubricant life-cycle and optimise changes without compromising lubrication system effectiveness.