viernes, 20 de diciembre de 2019

FUNDAMENTALS OF OIL ANALYSIS



By Eduardo Niño de Rivera
Special Edition: John Amendola Sr
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INTRUDUCTION:
There is a wide consensus described in technical literature [see references] regarding the best way to retrieve oil samples from lubricating systems. It is often stated that oil test results will only be valid if they are performed on samples that are representative of the oil in the system. A nonrepresentative sample may lead to erroneous conclusions regarding the condition of the oil itself and of the mechanical components it lubricates. If, for instance, the sample is more contaminated than the rest of the oil, we may conclude that the gears and bearings are in worse condition than they really are. Likewise, a sample that is cleaner than the rest of the oil, may lead us to believe that there is nothing wrong with components that may be approaching an imminent failure condition. In addition, the raw data of the analysis is meaningless without a proper interpretation

Whether oil samples are taken by plant personnel or by outside vendors, a technician with adequate training may extract the sample or supervise how it is done. An oil analysis is not a direct observation of the condition of the gears or bearings, it requires corroboration and proper interpretation to be a useful diagnostic tool. This article offers practical advice on how to properly take representative samples and on how to interpret test results.

THE FUNCTIONS OF LUBRICATING OIL.
Lubricating oil has three basic functions:
·         Reduce sliding and rolling friction in bearings, gears and seals;
·         Remove heat generated at sliding and rolling surfaces; and,
·         Protect surfaces from rusting and corroding.

Lubricating oil reduces friction by forming a sufficiently thick film between sliding surfaces to prevent them for making direct contact with each other. This requires the proper combination of load, sliding speed and oil viscosity. If the oil film is not thick enough, there will be direct metal to metal contact, leading to micropitting and/or scuffing, where metal particles are removed from the contacting surfaces. Although these particles will eventually sink to the bottom of the oil sump or they will be trapped by oil filters or magnetic plugs, they will remain in suspension within the oil for some time, contributing to abrasive ware or indentations that further deteriorate load bearing surfaces.



Lower friction in properly lubricated rolling and sliding surfaces contributes to keep the operating temperature at acceptable levels by removing heat as it flows away from the surfaces where it is generated.




The 3 regimes of lubrication, represented by the gray (sliding surfaces) and yellow (lubricant) images, are defined as follows:

Regime I: Boundary Lubrication. There is significant contact between the asperities of the sliding surfaces

Regime II: Mixed-Film Lubrication. There is contact only in the highest peaks of the asperities

Regime III: Hydrodynamic Lubrication: The oil film is sufficiently thick to completely separate the sliding surfaces.  

It is suggested but not proven, that surface distress due to scuffing occurs in the borderline between regime I & II,  it is an instantaneous phenomenon. Surface distress resulting in micropitting occurs in the borderline between regime II & III. Micropitting is a fatigue phenomenon and requires some load cycling.

When oil deteriorates due to time in service, contamination, exposure to high temperatures or adverse environmental conditions, it loses the ability to protect the metal surfaces against corrosion and abrasion thereby damaging the surfaces it was meant to protect.

MONITORING THE CONDITION OF LUBRICATING OIL.
The first step in designing a condition monitoring program for lubricating oil is to reach a clear understanding with a certified lab regarding how frequently the periodic oil tests should be performed; the reported formats and contents, including diagnostics and other information; referenced acceptable level for each variable in the report; and the number, location, identification, size, bottle specifications and gathering methods for the samples.

The Acceptable values for each variable should be agreed upon by the plant’s analysts and the lab based on the requirements of each machine. 

Periodic oil tests results and their evaluation over time, should provide the following information [1]:
·         The current condition of the oil;
·         How long the oil lasts begore it needs to be changed;
·         The presence of metallic particles as an indicator of bearing and gear wear; and
·         The trends in the frequency of oil changes and in quantity and composition of metallic particles and other contaminants mixed within the oil.

Oil tests performed outside the preestablished schedule may be required to assess the condition of gears and bearings when anomalous symptoms appear, such as an increase in temperature, noise or vibration.

A well-designed routine test program is a cost-effective way to determine whether oil characteristics and contamination levels are within acceptable limits [1]:
·         Oil viscosity at 40°C (100°C is also useful as representative of the operating condition);
·         Cleanliness;
·         Water Content;
·         Acid Number; and
·         Metal and other substances mixed within the oil.
If these measurements are within acceptable limits and there is no other indication of deterioration or damage to any components, the gearbox may continue in operation.


A single reading outside the acceptable values does not necessarily indicate that there is a problem with the gearbox, the problem may well be in the oil sample itself, so before making any transcendental or costly decisions, it is convenient to take a step by step approach to assess the condition of the components and to determine the underlying cause of deterioration and eventual failure:
·         Compare the unacceptable reading with other samples taken at the same time;
·         Submit a new sample to double check the results;
·         Review data provided by the condition monitoring system (temperature, noise and
vibrations);
·         Perform more detailed oil test;
·         Perform a direct inspection of the gears and bearings; and
·         Perform a detailed cause of failure analysis on gears and bearings.

Even when all the oil test variables are within acceptable values, it is important to keep track of their evolution over time. An upward trend in one or more variables may indicate that there is a deteriorating condition which will go undetected if current reports are not compared to past records. Spotting upward trends may allow us to take corrective action while the gearbox is still in operable condition, preventing catastrophic failures or unplanned machine downtime.



This cost-effective approach provides a solid base for an accurate diagnosis and sensible decisions.

WHERE TO TAKE SAMPLES
The oil within the system is not a homogeneous mix, so samples taken from different locations provide different pieces of information that may be put together to provide a more comprehensive view. If possible, AVOID TAKING SAMPLES FROM areas that are clearly not representative of the oil that reaches the gears and bearings, such as:
·         The bottom of the sump, where debris settles in much greater concentration than in the rest of the oil;
·         Downstream from filters that remove contaminants and wear debris generated at load bearing surfaces; or
·         Right after the oil has been changed.

Ideally, samples from sumps or reservoirs should be taken at approximately the middle of the oil depth, at least two inches away from the casing walls and from the immersed rotating components.

In circulating oil systems, samples may also be taken from the return lines, this should always be before the oil goes through filters. Samples taken from turbulent oil flow at piping bends are more representative of the general oil condition than those taken from the walls of straight tubing with laminar flow.

Be consistent. When taking an oil sample, extract it from the same relative location. Also do so at the same time; i.e 30 minutes after shutdown. If the system allows access while running, take the sample after the unit has reached a steady state operating condition. This can be verified by checking when the gear unit operating temperature has stabilized.


HOW TO TAKE SAMPLES
Samples must be free from outside contamination:
·         Use new or clean, perfectly dry bottles, tubing and other tools that may be in contact with the oil;
·         Clean ports, valves and plugs before connecting or opening;
·         If possible, avoid using the same tubes and hoses to retrieve different samples;
·         Flush and clean any tools or equipment before reusing them to collect a new sample;
·         Flush stagnant oil from pipes or tubing before collecting samples; and
·         Properly identify each sample taken (equipment, sampling point, time and date).

Use bottles or containers that meet the specifications agreed upon with the lab (material, shape and size).



CONSISTENCY OVER TIME
Permanently installed sample ports and valves (A) provide a very consistent means of retrieving samples from the same spot every time. These ports and valves can be conveniently located in return lines or in the gearbox casing to take representative samples as discussed above.  If there are no ports conveniently located in the casing, a bent pitot tube may solve the problem or new ports may need to be adapted on the gearbox.




A

B

C

D

E
 















In circulating oil systems, samples may be taken from return lines, preferably at pipeline bends, where the flow is turbulent (B). Avoid taking samples through side walls of straight-line laminar flow (D) and do not take samples of oil that has gone through a filter (E).  Low pressure lines will require vacuum pumps to extract oil samples.

Samples from sumps may also be taken with vacuum pumps, introducing a rigid or plastic tube through vent or filling plug openings (C). From outside the casing, it is difficult to control de exact location at the end of a flexible tube, so particular care must be taken to avoid taking samples from the bottom or near the walls of the casing. For better control and consistency, the flexible tube may be attached to a more rigid dip stick, this will make it easier to place the suction at approximately to the same spot every time.

B

D

E

C

C

D

E



SUMMARY:
THREE KEYS TO USEFULL OIL ANALYSIS

1.- SAMPLES. The data returned by the oil tests is only as good as the samples submitted:
·         The samples must be representative of the oil in the system;
·         Samples must not be contaminated during the gathering process;
·         Samples must be taken consistently over time;

2.- LAB REPORTS.
·         The tests should be performed by a certified lab;
·         The reports must return relevant data; and
·         The acceptable limits must be properly set for each test variable according to the requirements of each machine.

3.- INTERPRETATION.
·         The gearbox may continue in normal operation if all measurements are reported within acceptable limits and there is no other indication of an anomalous condition;
·         A single reading outside the limits should be confirmed before further action is taken;
·         Oil analysis is a useful indirect observation that points us in the right direction for immediate action but confirmation from other monitored variables, such as temperature, noise and vibration, or from direct observation of the components should be considered before committing to transcendental or costly decisions; and
·         Upward trends in reported values over time are early indicators of deteriorating mechanical components, costly repairs and unexpected down time may be prevented by addressing the underlying issues while the gearbox is still in operable condition.


CONCLUSION: 
Oil analysis is important not only because it lets us know if the oil is preforming properly as a lubricant, but also because the oil captures liquid and solid matter that is either penetrating from the outside or is being generated within the gearbox, reflecting the degree of deterioration of seals, bearings, gears and even the gearbox casing. Further, discrepancies and trends in the reported data may provide advanced warning of a deteriorating condition in mechanical components. Oil analysis is, therefore, a good indicator of health of the gearbox, however, it is not a direct observation of the actual condition of its components; it is useful as a non-invasive, cost-effective observation that can either sustain confidence to continue operating when the measurements are reported within acceptable limits and there is no other indicator of distress within the gearbox, or it can provide early warnings of anomalous conditions, yet, the findings must be confirmed by other condition monitoring methods or by direct observation of the internal gearbox components before transcendental or costly actions are taken.


References