A one-dimensional model for the motor oil-fuel dilution under gasoline engine boundary conditions

Mariani, Valerio; Bianchi, Gian Marco; Cazzoli, Giulio; Falfari, Stefania

doi:10.1051/e3sconf/202019706004

Cited by 3 publications

(5 citation statements)

References 23 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This model can be run as a stand-alone tool for global analysis and supporting tool paired with CFD codes for local and three-dimensional leak analysis. To model the hydrogen-lubricant interaction, a one-dimensional code was developed that simulates the dilution between lubricating oil and deposited liquid fuel [49,50]. It considers the mass diffusion between the two liquids, and their heating and evaporation by heat exchange with both walls and with the gases inside the combustion chamber.…”

Section: Oil-fuel Dilutionmentioning

confidence: 99%

Hydrogen Application as a Fuel in Internal Combustion Engines

et al. 2023

Self Cite

View full text Add to dashboard Cite

Hydrogen is the energy vector that will lead us toward a more sustainable future. It could be the fuel of both fuel cells and internal combustion engines. Internal combustion engines are today the only motors characterized by high reliability, duration and specific power, and low cost per power unit. The most immediate solution for the near future could be the application of hydrogen as a fuel in modern internal combustion engines. This solution has advantages and disadvantages: specific physical, chemical and operational properties of hydrogen require attention. Hydrogen is the only fuel that could potentially produce no carbon, carbon monoxide and carbon dioxide emissions. It also allows high engine efficiency and low nitrogen oxide emissions. Hydrogen has wide flammability limits and a high flame propagation rate, which provide a stable combustion process for lean and very lean mixtures. Near the stoichiometric air–fuel ratio, hydrogen-fueled engines exhibit abnormal combustions (backfire, pre-ignition, detonation), the suppression of which has proven to be quite challenging. Pre-ignition due to hot spots in or around the spark plug can be avoided by adopting a cooled or unconventional ignition system (such as corona discharge): the latter also ensures the ignition of highly diluted hydrogen–air mixtures. It is worth noting that to correctly reproduce the hydrogen ignition and combustion processes in an ICE with the risks related to abnormal combustion, 3D CFD simulations can be of great help. It is necessary to model the injection process correctly, and then the formation of the mixture, and therefore, the combustion process. It is very complex to model hydrogen gas injection due to the high velocity of the gas in such jets. Experimental tests on hydrogen gas injection are many but never conclusive. It is necessary to have a deep knowledge of the gas injection phenomenon to correctly design the right injector for a specific engine. Furthermore, correlations are needed in the CFD code to predict the laminar flame velocity of hydrogen–air mixtures and the autoignition time. In the literature, experimental data are scarce on air–hydrogen mixtures, particularly for engine-type conditions, because they are complicated by flame instability at pressures similar to those of an engine. The flame velocity exhibits a non-monotonous behavior with respect to the equivalence ratio, increases with a higher unburnt gas temperature and decreases at high pressures. This makes it difficult to develop the correlation required for robust and predictive CFD models. In this work, the authors briefly describe the research path and the main challenges listed above.

show abstract

Section: Oil-fuel Dilutionmentioning

confidence: 99%

Hydrogen Application as a Fuel in Internal Combustion Engines

et al. 2023

Self Cite

View full text Add to dashboard Cite

show abstract

“…Furthermore, the Authors implemented the liquid fuel as a multicomponent mixture with different diffusion rate for each component. In [17] Mariani et al the Authors presented an improved version of the model by Zhang for the oil-fuel dilution analysis by enhancing the features of the diffusion model with the use of a new hybrid deep neural networks methodology for predicting the binary diffusion coefficient between engine oils and typical gasoline fuels. Furthermore, additional care was placed in the mixing rules for the calculation of the oil-fuel mixture properties depending on both temperature and composition.…”

Section: Commercial Gasoline Hydrogenmentioning

confidence: 99%

“…Finally, the normal boiling point of the lubricant oil is calculated with a dedicated sub-model, being evaporation properties not additive. The sub-model is based on the zero-dimensional distillation model developed by Mariani et al [17], which is based on the works of Slavinskaya et al [31] and Abianeh et Al. [32], allowing to evaluate the first boiling temperature by means of a pure thermodynamic model.…”

Section: Propertiesmentioning

confidence: 99%

A Numerical Methodology to Test the Lubricant Oil Evaporation and Its Thermal Management-Related Properties Derating in Hydrogen-Fueled Engines

De Renzis,

Mariani,

Bianchi

et al. 2023

SAE Int. J. Engines

Self Cite

View full text Add to dashboard Cite

<div>Due to the incoming phase out of fossil fuels from the market in order to reduce the carbon footprint of the automotive sector, hydrogen-fueled engines are candidate mid-term solution. Thanks to its properties, hydrogen promotes flames that poorly suffer from the quenching effects toward the engine walls. Thus, emphasis must be posed on the heat-up of the oil layer that wets the cylinder liner in hydrogen-fueled engines. It is known that motor oils are complex mixtures of a number of mainly heavy hydrocarbons (HCs); however, their composition is not known a priori. Simulation tools that can support the early development steps of those engines must be provided with oil composition and properties at operation-like conditions. The authors propose a statistical inference-based optimization approach for identifying oil surrogate multicomponent mixtures. The algorithm is implemented in Python and relies on the Bayesian optimization technique. As a benchmark, the surrogate for the SAE5W30 commercial multigrade oil has been determined. Then, this multicomponent surrogate and a SAE5W30 pseudo-pure are compared by means of an oil film model, which accounts for oil heat exchange with the cylinder wall and the gases from hydrogen combustion, and its evaporation. The results in terms of oil film temperature, viscosity, and thickness under hydrogen-engine boundaries are evaluated. Analyses reveal that the optimized multicomponent mixture behavior is more realistic and can outperform the pseudo-pure approach when the oil phase change and the oil-in-cylinder presence must be considered.</div>

show abstract

“…These compositions are needed as inputs in a mass and thermal diffusion and evaporation numerical model, now briefly described. This model relies on a previous work by the present authors [20] and allows to evaluate the lubricant oil evaporation, while accounting for the mutual diffusion among its components and the temperature dependency of its properties during the working cycle of a hydrogen-fuelled ICE. The computational domain is composed by the cylinder liner wall, the lubricant oil layer and a moving boundary to address lubricant oil evaporation, thus, the layer thickness reduction during the simulation.…”

Section: Diffusion and Evaporation Modelmentioning

confidence: 99%

“…They used a lubricant oil surrogate based on n-hexadecane and developed a reduced reaction mechanism that allowed to discover that lubricant oil significantly facilitates the mixture ignition at lower temperatures with respect to those typical of hydrogen autoignition. Concerning lubricant oil -fuel dilution and fuel evaporation, Mariani et al [20] [21] developed a one-dimensional lubricant oil -fuel dilution model which is able to qualitatively predict the lubricant oil deterioration due to fuel impact on the cylinder liner wall. Though, attention must be paid on the fact that these models does not account for lubricant oil evaporation, being the characteristic temperatures of gasoline combustion lower with respect to hydrogen combustion, thus not enabling oil evaporation.…”

Section: Introductionmentioning

confidence: 99%

Application of a One-Dimensional Dilution and Evaporation Lubricant Oil Model to Predict Oil Evaporation under Different Engine Operative Conditions Considering a Large Hydrogen-Fuelled Engine

De Renzis,

Mariani,

Bianchi

et al. 2023

SAE Technical Paper Series

Self Cite

View full text Add to dashboard Cite

<div class="section abstract"><div class="htmlview paragraph">The increasing environmental concern is leading to the need for innovation in the field of internal combustion engines, in order to reduce the carbon footprint. In this context, hydrogen is a possible mid-term solution to be used both in conventional-like internal combustion engines and in fuel cells (for hybridization purposes), thus, hydrogen combustion characteristics must be considered. In particular, the flame of a hydrogen combustion is less subjected to the quenching effect caused by the engine walls in the combustion chamber. Thus, the significant heating up of the thin lubricant layer upon the cylinder liner may lead to its evaporation, possibly and negatively affecting the combustion process, soot production. The authors propose an analysis which aims to address the behavior of different typical engine oils, (SAE0W30, SAE5W30, SAE5W40) under engine thermo-physical conditions considering a large hydrogen-fuelled engine. The operative conditions are obtained by means of simulations through a zero-dimensional engine model in <i>OpenWAM</i> environment. The lubricant oils composition and properties are defined by means of a statistical interference-based optimization approach which identifies the most proper mixture of heavy hydrocarbons as a surrogate of real oils. Then, the mixture is implemented in an in-house developed heat and mass transfer one-dimensional model which accounts for the lubricant oil evaporation and the mutual diffusion between the oil surrogate components. This work aims to test and analyze the response of different lubricant oils to heating and evaporation processes during the compression and combustion stroke of a hydrogen-fuelled internal combustion engine. The behaviour and the properties evolution during the compression and part of the expansion strokes of different lubricant oils in two different engine operative conditions are captured and discussed.</div></div>

show abstract

A one-dimensional model for the motor oil-fuel dilution under gasoline engine boundary conditions

Cited by 3 publications

References 23 publications

Hydrogen Application as a Fuel in Internal Combustion Engines

Hydrogen Application as a Fuel in Internal Combustion Engines

A Numerical Methodology to Test the Lubricant Oil Evaporation and Its Thermal Management-Related Properties Derating in Hydrogen-Fueled Engines

Application of a One-Dimensional Dilution and Evaporation Lubricant Oil Model to Predict Oil Evaporation under Different Engine Operative Conditions Considering a Large Hydrogen-Fuelled Engine

Contact Info

Product

Resources

About