The analysis of power train lubricants for the purpose of detecting faults and abnormal wear patterns is a well developed practiced in mobile equipment applications. However, these same techniques don’t always transfer successfully into stationary equipment applications for many users. In recent years new approaches and techniques have been perfected to substantially improve the detection of incipient and developing faults in bearings and gear units using wear debris analysis. The approach is more systemic as opposed to the application of any singular new or emerging technology. It begins with improvements in the sampling process to enrich the data and proceeds through the use of tactics that strengthen the signal-to-noise ratio. After detection is confirmed, the final analytical phase involves wear particle identification using both classic and advanced techniques. Key Words: wear debris analysis, spectroscopy, wear particles, ferrography, fault detection, predictive maintenance, tribology, wear particle identification, oil analysis, condition monitoring, elemental analysis, ferrous density, microscopic analysis, ferrometrics.

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The analysis of power train lubricants for the purpose of detecting faults and abnormal wear patterns is a well developed practice in mobile equipment applications. However, these same techniques don’t always transfer successfully into stationary equipment applications for many users.

In recent years new approaches and techniques have been advanced to substantially improve the detection of incipient and developing faults in bearings and gear units using wear debris analysis. The approach is more systemic as opposed to the application of any singular new or emerging technology.

It begins with improvements in the sampling process to enrich the data and proceeds through the use of specific strategies and tactics. After detection is confirmed, the final analytical phase involves wear particle identification using both classic and advanced techniques.

The post Maximizing Fault Detection in Rotating Equipment Using Wear Debris Analysis appeared first on Tesibis.

The analysis of powertrain lubricants for the purpose of detecting faults and abnormal wear patterns is a useful practice in mobile equipment applications. Unfortunately for many users, these techniques don’t always transfer successfully into stationary equipment applications. In recent years, new approaches and techniques have been advanced to improve the detection of incipient and developing faults in bearings and gear units using wear debris analysis.

As opposed to the application of any singular new or emerging technology, these new methods are more systematic and functional. It begins with improvements in the sampling process to enrich the data and proceeds through the use of specific strategies and tactics. After detection is confirmed, the final analytical phase involves wear particle identification using both classic and advanced techniques.

Like so many endeavors, success depends more on the quality of execution than the strength of the underlying technologies. This idea can be concluded from the fact that while a great deal of new knowledge and technology has been advanced, for the vast majority of industrial organizations employing wear debris analysis, little has changed in either their tools or approach.

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This isn’t your usual article on how important clean oil is to lubricant health and machine reliability. Yes, we are going to talk about particle contamination, but we’re going to take a much closer look at the destructive traits of this nearly invisible material that cohabitates with our lubricants.

As it turns out, there is a lot more to particles than their size and count. This column will peer into the intricacies of the physical and chemical properties that make up and characterize solid particle contamination.

I’ll begin by discussing 10 particle characteristics that should be important to lubricant analysts and lubrication professionals. Each of these characteristics or traits influences the health of lubricated machinery. While the name of the trait may be familiar, the damage it causes may not be.

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I often mention the wear debris universe when I lecture on oil analysis topics. This refers to the extensive array of wear particle technologies and tactics that can help reveal the true tribological condition of a machine.

Individually, these tools are often inconclusive when it comes to identifying the source, cause and severity of abnormal wear conditions. They may not even be able to identify the problem at all. Yet when used in combination, they can expose a vivid image of a current or impending failure condition.

A skilled analyst should be well aware of the strengths and weaknesses of these technologies and tactics. Not all of these tools need to be at your fingertips, but nonetheless should be available when called upon. Too often, an inexperienced technician will attempt to draw a premature conclusion from little more than a sliver of information in the wear debris universe.

Examples might be a muted iron trend from elemental data or stabilized ISO codes from particle counting. Used alone, these technologies might telegraph to the diagnostician the erroneous appearance of machine health (or disease). Unseen may be an incipient but serious wear condition in need of attention.

Common front-line technologies used for screening purposes include ferrous density analysis, elemental spectroscopy, particle counting and patch testing. Collectively, these technologies pack a powerful punch and are credited with scores of predictive maintenance “saves”.

However, in a high percentage of cases, these technologies would not have earned their hero status if it weren’t for the other tests and methods that peered deeper into the core of the problem.

These include secondary sampling points, filter debris inspection, magnetic plug analysis, sump sediment analysis, SEM-EDS, XRF, ferrography (all methods), acid-dissolution spectroscopy, particle heat treatment, particle impaction testing, chemical microscopy, digital shape profiling, percent of large ferrous particles, rotrode filter spectroscopy, TGA, gravimetric analysis, ultracentrifuge (separation of soluble metal fraction), pore blockage particle counting … and the list goes on.

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