Evaluation of lubricating oil in marine diesel engine using thermal analysis, FTIR, and rheology

Analysis of used lubricating oils is one of the tools that enable the diagnosis of the operation condition of the engine, and it is a widespread predictive maintenance practice in the marine sector. This study aimed to evaluate by thermal analysis, FTIR and rheology, lubricating oils before and afte...

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Bibliographic Details
Published in:Journal of thermal analysis and calorimetry 2022-12, Vol.147 (23), p.13261-13274
Main Authors: Santana, Naienne da Silva, Silva, Gean Almeida, Mothé, Cheila Gonçalves, Mothé, Michelle Gonçalves
Format: Article
Language:English
Subjects:
Absorption spectra
Additives
Analytical Chemistry
Carbonyl groups
Carbonyls
Chemistry
Chemistry and Materials Science
Depletion
Diesel engines
Diesel motor
Inorganic Chemistry
Integrity
Internal combustion engine industry
Lubricants
Lubricants industry
Lubricating oils
Lubrication and lubricants
Maintenance and repair
Marine engines
Measurement Science and Instrumentation
Oxidation
Petroleum products
Physical Chemistry
Polymer Sciences
Predictive maintenance
Rheological properties
Rheology
Stability analysis
Thermal analysis
Thermal degradation
Thermal stability
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Summary:Analysis of used lubricating oils is one of the tools that enable the diagnosis of the operation condition of the engine, and it is a widespread predictive maintenance practice in the marine sector. This study aimed to evaluate by thermal analysis, FTIR and rheology, lubricating oils before and after use in diesel marine engine and their additives, to monitor the physical integrity of these materials by evaluating their physical and chemical stability. Samples with 5280 and 8242 h of use showed thermal degradation profiles similar to unused lubricant oil on the TG curves. In contrast, a one with 7498 h of use presented higher thermal stability than the new lubricant, with only one stage of decomposition from 225 to 400 °C, indicating that their additives were probably no longer present in their original structure. That was confirmed by the FTIR spectrum of this sample, which showed scarce absorption bands of additives at their characteristic wavenumbers and distinctive bands of carbonyl groups indicating oil oxidation. This same sample also presented the lowest viscosity values on rheological tests, confirming the depletion of additives. On the other hand, the characterization techniques showed that the sample with 8242 h of use, with more hours of operation, maintained its physical–chemical integrity compared to unused lubricating oil.
ISSN:1388-6150
1588-2926
DOI:10.1007/s10973-022-11568-1