⎪ Maintenance and asset management ⎪
dant, the result is an accurate representation of the real remaining antioxidant potential. However, when the remaining antioxidants are very low and the peaks are shallow, it is possible to make errors in the antioxidant quantification, typically in excess. To avoid falling into this analytical pit, it is possible to better estimate the remaining antioxidant % by extrapolation. This involves preparing and testing a few new and used oil refreshment samples to cover 0%, 20%, 40%, 60% and 100% oil refreshments. In the case of a Gas Turbine using ISO VG 32 mineral lubricant with an R&O package and 43 000 operation hours, for example, RULER resulted in 28.3% remaining antioxidant, very close to the condemning limit. To better assess the RULER value, the extrapolation method was performed, with mixtures of new and used oil covering 0% to 100% refreshments. After thorough homogenisation, Figure 3(a) and 3(b) show the RULER outcome. Given that the prepared samples are a mixture of new and used oil, the remaining antioxidant % must be linear. However, if we plot these results (Figure 3b), we can see how the in-service oil (0% refreshment) clearly falls out of the linear curve. Hence, the actual remaining antioxidant concentration in the in-service oil is 14,9% (y-intercept) and not 28,3% as would have been estimated by the traditional RULER method. Through RULER analysis, it is also possible to check the synergy between antioxidant chemistries. Turbines usually operate using a mixture of phenol and amine antioxidants in the lubricant. Amines are reactive anti- oxidants which rapidly take free radicals, protecting the base oils by terminating chain reactions, which would degrade the base oil. Hindered phenols are slower reactants but they have the potential to regenerate the oxidised amines and become stable free radi- cals themselves (see the full technical bulletin paper for more detail). Estimating lubricant refreshment In order to build a model for lubricant refresh- ment for turbines, one must assess the differ- ent scenarios that exist between the actual condition of the turbine and a hypothetical situation resulting in a full lubricant change. WearCheck’s Technical Bulletin 81 pres- ents the details of such a study based on a gas turbine that is lubricated with a Group I – ISO VG 32 oil with aminic antioxidants. The lubricant has been in service for 43 000 hours. Refreshment strategies There are several strategies for maintaining high doses of antioxidants and oxidation con- dition within reliability parameters. The first
Figure 2: RPVOT curves for different base oil formulations.
species taking place inside the turbine to form varnish. To achieve high reliability, the compatibil- ity and performance of both the concentrate and the reformulated oil must be extensively tested in a laboratory. Testing must include characterisation of the resulting physical properties, functional properties such as foaming, air release, demulsibility and prog- nostics on the ageing and resulting oxidation condition of the reformulation. Lastly, tests defying deposit formation must be passed. Once the chemistry of the ad- ditive replenishment is adequately tested, the in-plant execution must be carefully driven by recognised technicians. This accounts for as- suring adequate mixing of the fluids, avoiding precipitation, and having a contingency plan if deposit formation should arise. In conclusion, additive replenishment is the best option from the economical perspec- tive. From the technical perspective, excellent
line in keeping the antioxidants high is regular lubricant top-up, which refreshes up to about 5% of the lubricant per year, adding some fresh antioxidants into the system, but not usually enough to satisfy the total oxidation rate in a turbine. So, an additional strategy must be applied. There are two possible paths to follow: either bleed and feed or antioxidant replen- ishment. Bleed and feed is the conservative option. This option is expensive from an eco- nomical perspective, because when bleeding oil from the turbine, unless the oxidation has gone too far, the base oil molecules are usu- ally not oxidised (Livingstone, 2014). Only the antioxidants (1%) typically need refreshment, while 99% of the base oil is wasted. However, performing bleed and feed is the safest pro- cedure for refreshing lubricant and is a fast operation. Depending on the turbine and on the required refreshment %, bleed and feed can be done without stopping operations and with minimal down time. The second possible strategy is additive replenishment. In this strategy, an antioxidant concentrate is slowly fed to the turbine oil with minimal in-service oil bleed. In this way, the base oil is conserved, and antioxidants are re-dosed to a desired level. This strategy must be carried out by an experienced formulator who has an intimate knowledge of the chem- istry of the base oil and the antioxidants in the system, along with the chemistry of the deposits formed in this system. Additive chemistries interact, and this interaction can either be synergistic or antagonistic. Synergy accounts for the re- generation of aminic front-line antioxidants by fresh phenolic antioxidants. On the other hand, when turbine oil forms varnish, these are heavily composed of both fresh and oxidised antioxidants. When reformulating in-service oil, it is of utmost importance that formulation-derived deposits are not formed. One major issue is that when adding antioxidants to an in-service oil, the total anti- oxidant concentration, dead or alive, rises and, without keen knowledge of the system, this may easily result in antioxidant precipitation or undesired reactions between antioxidant
results can be achieved, and successful projects have multi- plied many in-service periods of turbine oils. www.wearcheck.co.za/ shared/TB81.pdf
RULER can be quantified by extrapolation in degraded samples: Figure 3(a) shows amperograms for refreshment samples of a Group I Turbine Oil together with their quantification. In Figure 3(b), the data is plotted, showing the original sample (0% refreshment) falling off the linear plot.
January-February 2023 • MechChem Africa ¦ 7
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