CFD Modeling of an Alcohol-Diesel Direct-Injection Dual-Liquid-Fuel Engine using OpenFOAM
Doktorsavhandling, 2021
Legislation for heavy duty combustion engines are becoming more stringent. To keep up with the legislation, new engine technology is required. Furthermore, renewable fuels can also be used together with new engine technology to further reduce emissions.
Computational techniques such as Computational Fluid Dynamics (CFD) provides a powerful and cost effective alternative/complement to traditional engine tests when developing new engine technology. To effectively use CFD for engine development, accurate models for spray formation and chemistry are required. In this work a new direct-injection dual-liquid-fuel engine concept using methanol and diesel was investigated using CFD. The first part of this thesis involved validation and development of our in-house spray model, VSB2. The VSB2 is a Eulerian-Lagrangian model with a minimal amount of tuning parameter. It models the impact of secondary breakup by including a distribution of droplet sizes inside each computational blob. The model was first validated for use with alcohol fuels, where the turbulence parameters were also tuned together with experimental data for later use in engine
simulations. It was shown that the VSB2 spray model could accurately predict the spray formation of an alcohol spray.
Furthermore, the spray model was developed further by implementing a new break up treatment that addressed some conceptual flaws in how the model handles the momentum of a computational blob with different droplet sizes. Previously, each computational blob contained the momentum of all droplet sizes, which had the consequence that smaller droplets would have the same momentum as larger droplets. This was addressed by creating child blobs from the stable droplet sizes. It was shown that this had the effect of enhancing the evaporation and dispersion at lower ambient gas temperatures.
The last part of this thesis was to create a CFD model in OpenFOAM that could model a direct-injection dual-liquid-fuel engine. A tabulated chemistry solver based on the well stirred reactor approach called LOGE-CPV was used to model the chemistry. It was shown that the model could accurately predict global parameters such as in cylinder pressure and rate of heat release of the system, but pollutant formation was predicted poorly when compared to experiments. It was concluded that a turbulent combustion model would be needed to accurately predict pollutant formation. The ignition process was also studied, showing that the pilot diesel could easily ignite the methanol as long as the pilot flame would reach the center of the combustion chamber. It was also shown that further offsetting the pilot injector caused the combustion to become unstable as it was difficult to ignite all
the sprays from the main injector.
Computational techniques such as Computational Fluid Dynamics (CFD) provides a powerful and cost effective alternative/complement to traditional engine tests when developing new engine technology. To effectively use CFD for engine development, accurate models for spray formation and chemistry are required. In this work a new direct-injection dual-liquid-fuel engine concept using methanol and diesel was investigated using CFD. The first part of this thesis involved validation and development of our in-house spray model, VSB2. The VSB2 is a Eulerian-Lagrangian model with a minimal amount of tuning parameter. It models the impact of secondary breakup by including a distribution of droplet sizes inside each computational blob. The model was first validated for use with alcohol fuels, where the turbulence parameters were also tuned together with experimental data for later use in engine
simulations. It was shown that the VSB2 spray model could accurately predict the spray formation of an alcohol spray.
Furthermore, the spray model was developed further by implementing a new break up treatment that addressed some conceptual flaws in how the model handles the momentum of a computational blob with different droplet sizes. Previously, each computational blob contained the momentum of all droplet sizes, which had the consequence that smaller droplets would have the same momentum as larger droplets. This was addressed by creating child blobs from the stable droplet sizes. It was shown that this had the effect of enhancing the evaporation and dispersion at lower ambient gas temperatures.
The last part of this thesis was to create a CFD model in OpenFOAM that could model a direct-injection dual-liquid-fuel engine. A tabulated chemistry solver based on the well stirred reactor approach called LOGE-CPV was used to model the chemistry. It was shown that the model could accurately predict global parameters such as in cylinder pressure and rate of heat release of the system, but pollutant formation was predicted poorly when compared to experiments. It was concluded that a turbulent combustion model would be needed to accurately predict pollutant formation. The ignition process was also studied, showing that the pilot diesel could easily ignite the methanol as long as the pilot flame would reach the center of the combustion chamber. It was also shown that further offsetting the pilot injector caused the combustion to become unstable as it was difficult to ignite all
the sprays from the main injector.
Renewable Fuels
Dual-Fuel Combustion
CFD
Spray Modeling
Zoom (Password: 268947)
Opponent: Professor Gianluca D'errico, Politecnico di Milano, Italy
Författare
Andreas Nygren
Chalmers, Mekanik och maritima vetenskaper, Förbränning och framdrivningssystem
A COMPREHENSIVE STUDY ON THE INFLUENCE OF RESOLVING AN INJECTOR ORIFICE AND THE INFLUENCE OF CREATING STRIPPED OFF DROPLETS ON SPRAY FORMATION USING THE VSB2 SPRAY MODEL
Atomization and Sprays,; Vol. 31(2021)p. 15-55
Artikel i vetenskaplig tidskrift
A study of ECN spray a using an improved stochastic blob (VSB2) spray model
ICLASS 2018 - 14th International Conference on Liquid Atomization and Spray Systems,; (2020)
Paper i proceeding
Validation of the VSB2 Spray Model for Ethanol under Diesel like Conditions
SAE Technical Papers,; Vol. 2017-October(2017)
Artikel i vetenskaplig tidskrift
Our planet is currently undergoing some serious changes. Global warming is a real problem right now. Driving cars and trucks that run on fossil fuels are contributing to the increase in global warming. It is therefore very important that we develop cars and trucks that can run on efficient engines and clean fuels. The work that was done in this thesis contributed to developing a new type of engine for trucks. This new engine concept uses two fuels instead of the usual one. It runs on both Diesel and methanol. Methanol is an alcohol fuel that can be produced without digging up oil or natural gas from the ground. Since methanol can be difficult to ignite on its own, we use a small amount of diesel to ignite it. In this thesis, mathematical computer models was used to predict how such an engine would behave. Using computer models can save both time and money compared to building a brand new engine and do experiments. It can also give detailed insight that is not possible to get otherwise.
The work done in the thesis showed that an engine that run on both methanol and diesel would produce less green house gas emissions than a pure diesel engine.
The work done in the thesis showed that an engine that run on both methanol and diesel would produce less green house gas emissions than a pure diesel engine.
Bränsleflexibel motorplattform (FLEX II)
Energimyndigheten (39368-2,2018-008000), 2018-10-01 -- 2020-09-30.
Bränsleflexibel motorplattform (FLEX I)
Energimyndigheten (P39368-1), 2015-01-01 -- 2017-10-01.
Ämneskategorier
Maskinteknik
Styrkeområden
Transport
ISBN
978-91-7905-461-8
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 4928
Utgivare
Chalmers