Details
Modeling of Real Fuels and Knock Occurrence for an Effective 3D-CFD Virtual Engine Development
Wissenschaftliche Reihe Fahrzeugtechnik Universität Stuttgart
53,49 € |
|
Verlag: | Springer Vieweg |
Format: | |
Veröffentl.: | 14.09.2020 |
ISBN/EAN: | 9783658316280 |
Sprache: | englisch |
Dieses eBook enthält ein Wasserzeichen.
Beschreibungen
<p>To drastically reduce the emission of greenhouse gases, the development of future internal combustion engines will be strictly linked to the development of CO<sub>2</sub> neutral fuels (e.g. biofuels and e-fuels). This evolution implies an increase in development complexity, which needs the support of engine 3D-CFD simulations. Francesco Cupo presents approaches to accurately describe fuel characteristics and knock occurrence in SI engines, thus improving the current simulation capability in investigating alternative fuels and innovative combustion processes. The developed models are successfully used to investigate the influence of ethanol-based fuels and water injection strategies on knock occurrence and to conduct a virtual fuel design for and engine operating with the innovative SACI combustion strategy.</p>
<div>Detailed description of real fuels.- Locally-distributed auto-ignition model and knock detection.- Influence of ethanol-based fuels and water injection on combustion and knock.- Virtual fuel design for SACI combustion strategy.</div>
<p><b>Francesco Cupo</b> obtained a PhD at the research Institute of Automotive Engineering (IFS) in Stuttgart, Germany. His activity is currently focusing on the design of advanced internal combustion engines and alternative fuels.</p>
<div>To drastically reduce the emission of greenhouse gases, the development of future internal combustion engines will be strictly linked to the development of CO2 neutral fuels (e.g. biofuels and e-fuels). This evolution implies an increase in development complexity, which needs the support of engine 3D-CFD simulations. Francesco Cupo presents approaches to accurately describe fuel characteristics and knock occurrence in SI engines, thus improving the current simulation capability in investigating alternative fuels and innovative combustion processes. The developed models are successfully used to investigate the influence of ethanol-based fuels and water injection strategies on knock occurrence and to conduct a virtual fuel design for and engine operating with the innovative SACI combustion strategy.</div><div><br></div><div><b>Contents</b></div><div><ul><li>Detailed description of real fuels</li><li>Locally-distributed auto-ignition model and knock detection</li><li>Influence of ethanol-based fuels and water injection on combustion and knock</li><li>Virtual fuel design for SACI combustion strategy</li></ul></div><div><b>Target Groups</b></div><div><ul><li>Researchers and students in the field of automotive engineering</li><li>Automotive engineers</li></ul></div><div><b>The Author</b></div><div><b>Francesco Cupo </b>obtained a PhD at the research Institute of Automotive Engineering (IFS) in Stuttgart, Germany. His activity is currently focusing on the design of advanced internal combustion engines and alternative fuels.</div><div><br></div>
Virtual investigation of alternative fuels and innovative combustion processes
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