An Experimental Investigation of the Impact of Additive Concentration on the Tribological Performance of Castor Oil Lubrication in Piston Ring–Cylinder Liner Contact

An Experimental Investigation of the Impact of Additive Concentration on the Tribological Performance of Castor Oil Lubrication in Piston Ring–Cylinder Liner Contact

This experimental study investigates the critical role and impact of additive concentration in enhancing the tribological performance of castor oil as a biolubricant for agricultural tractor engines. Friction and wear are major contributors to reduced engine efficiency, highlighting the need for eff...

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Bibliographic Details
Main Authors: Wasihun Diriba Keno, Ádám Kalácska, Dieter Fauconnier, Venkata Ramayya Ancha, Patrick De Baets
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Lubricants
Subjects:
IC engine
lubrication
additive concentration
castor oil
friction
wear
Online Access:https://www.mdpi.com/2075-4442/13/5/206
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Summary:This experimental study investigates the critical role and impact of additive concentration in enhancing the tribological performance of castor oil as a biolubricant for agricultural tractor engines. Friction and wear are major contributors to reduced engine efficiency, highlighting the need for effective lubrication strategies. While biolubricants like castor oil offer environmental benefits, they often require additives to achieve optimal performance. However, the concentration of these additives is crucial, as an imbalance can negatively impact the lubrication system, leading to a higher coefficient of friction, increased wear, and reduced engine efficiency and lifespan. This study examines the effects of varying concentrations of a mixture of propyl gallate (PG) and ionic liquid (IL) additives on the tribological performance of castor oil. The tribological behaviour of lubricated top compression piston ring and cylinder liner samples was evaluated under simulated engine conditions using a Bruker UMT Tribolab test rig, in accordance with the ASTM G181 standard. The experimental results revealed an influence of additive concentration on the coefficient of friction and wear behaviour. This emphasises the importance of optimising additive formulations to minimise engine wear and friction. Notably, a 0.5% volume concentration of the additive mixture led to a remarkable 34.8% reduction in the average coefficient of friction (COF) and a lower wear rate.
ISSN:2075-4442

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