Standard and consistent Detached-Eddy Simulation for turbulent engine flow modeling: an application to the TCC-III engine
Multidimensional modeling of Cycle-to-Cycle Variability (CCV) has become a crucial support for the development and optimization of modern direct-injection turbocharged engines. In that sense, the only viable modeling options is represented by scale-resolving approaches such as Large Eddy Simulation...
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EDP Sciences
2020-01-01
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| Series: | E3S Web of Conferences |
| Online Access: | https://www.e3s-conferences.org/articles/e3sconf/pdf/2020/57/e3sconf_ati2020_06021.pdf |
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doaj-158c55ac54b64a439e847706e253464d2021-04-02T11:09:11ZengEDP SciencesE3S Web of Conferences2267-12422020-01-011970602110.1051/e3sconf/202019706021e3sconf_ati2020_06021Standard and consistent Detached-Eddy Simulation for turbulent engine flow modeling: an application to the TCC-III engineKrastev Vesselin Krassimirov0Di Ilio Giovanni1Iacovano Clara2d’Adamo Alessandro3Fontanesi Stefano4Department of Enterprise Engineering “Mario Lucertini”, University of Rome “Tor Vergata”Department of Engineering, University of Naples “Parthenope” Centro Direzionale, Isola C4DIEF “Enzo Ferrari” Engineering Department, University of Modena and Reggio EmiliaDIEF “Enzo Ferrari” Engineering Department, University of Modena and Reggio EmiliaDIEF “Enzo Ferrari” Engineering Department, University of Modena and Reggio EmiliaMultidimensional modeling of Cycle-to-Cycle Variability (CCV) has become a crucial support for the development and optimization of modern direct-injection turbocharged engines. In that sense, the only viable modeling options is represented by scale-resolving approaches such as Large Eddy Simulation (LES) or hybrid URANS/LES methods. Among other hybrid approaches, Detached-Eddy Simulation (DES) has the longest development story and is therefore commonly regarded as the most reliable choice for engineering-grade simulation. As such, in the last decade DESbased methods have found their way through the engine modeling community, showing a good potential in describing turbulence-related CCV in realistic engine configurations and at reasonable computational costs. In the present work we investigate the in-cylinder modeling capabilites of a standard two-equation DES formulation, compared to a more recent one which we call DESx. The DESx form differs from standard DES in the turbulent viscosity switch from URANS to LES-like behavior, which for DESx is fully consistent with Yoshizawa’s one-equation sub-grid scale model. The two formulations are part of a more general Zonal-DES (ZDES) methodology, developed and validated by the authors in a series of previous publications. Both variants are applied to the multi-cycle simulation of the TCC-III experimental engine setup, using sub-optimal grid refinement levels in order to stress the model limitations in URANS-like numerical resolution scenarios. Outcomes from this study show that, although both alternatives are able to ouperform URANS even in coarse grid arrangements, DESx emerges as sligthly superior and thus it can be recommended as the default option for in-cylinder flow simulation.https://www.e3s-conferences.org/articles/e3sconf/pdf/2020/57/e3sconf_ati2020_06021.pdf |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Krastev Vesselin Krassimirov Di Ilio Giovanni Iacovano Clara d’Adamo Alessandro Fontanesi Stefano |
| spellingShingle |
Krastev Vesselin Krassimirov Di Ilio Giovanni Iacovano Clara d’Adamo Alessandro Fontanesi Stefano Standard and consistent Detached-Eddy Simulation for turbulent engine flow modeling: an application to the TCC-III engine E3S Web of Conferences |
| author_facet |
Krastev Vesselin Krassimirov Di Ilio Giovanni Iacovano Clara d’Adamo Alessandro Fontanesi Stefano |
| author_sort |
Krastev Vesselin Krassimirov |
| title |
Standard and consistent Detached-Eddy Simulation for turbulent engine flow modeling: an application to the TCC-III engine |
| title_short |
Standard and consistent Detached-Eddy Simulation for turbulent engine flow modeling: an application to the TCC-III engine |
| title_full |
Standard and consistent Detached-Eddy Simulation for turbulent engine flow modeling: an application to the TCC-III engine |
| title_fullStr |
Standard and consistent Detached-Eddy Simulation for turbulent engine flow modeling: an application to the TCC-III engine |
| title_full_unstemmed |
Standard and consistent Detached-Eddy Simulation for turbulent engine flow modeling: an application to the TCC-III engine |
| title_sort |
standard and consistent detached-eddy simulation for turbulent engine flow modeling: an application to the tcc-iii engine |
| publisher |
EDP Sciences |
| series |
E3S Web of Conferences |
| issn |
2267-1242 |
| publishDate |
2020-01-01 |
| description |
Multidimensional modeling of Cycle-to-Cycle Variability (CCV) has become a crucial support for the development and optimization of modern direct-injection turbocharged engines. In that sense, the only viable modeling options is represented by scale-resolving approaches such as Large Eddy Simulation (LES) or hybrid URANS/LES methods.
Among other hybrid approaches, Detached-Eddy Simulation (DES) has the longest development story and is therefore commonly regarded as the most reliable choice for engineering-grade simulation. As such, in the last decade DESbased methods have found their way through the engine modeling community, showing a good potential in describing turbulence-related CCV in realistic engine configurations and at reasonable computational costs.
In the present work we investigate the in-cylinder modeling capabilites of a standard two-equation DES formulation, compared to a more recent one which we call DESx. The DESx form differs from standard DES in the turbulent viscosity switch from URANS to LES-like behavior, which for DESx is fully consistent with Yoshizawa’s one-equation sub-grid scale model. The two formulations are part of a more general Zonal-DES (ZDES) methodology, developed and validated by the authors in a series of previous publications. Both variants are applied to the multi-cycle simulation of the TCC-III experimental engine setup, using sub-optimal grid refinement levels in order to stress the model limitations in URANS-like numerical resolution scenarios. Outcomes from this study show that, although both alternatives are able to ouperform URANS even in coarse grid arrangements, DESx emerges as sligthly superior and thus it can be recommended as the default option for in-cylinder flow simulation. |
| url |
https://www.e3s-conferences.org/articles/e3sconf/pdf/2020/57/e3sconf_ati2020_06021.pdf |
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