Tesi etd-04082014-190145 |
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Tipo di tesi
Tesi di laurea magistrale
Autore
FERRAROTTI, MARCO
URN
etd-04082014-190145
Titolo
Pollutant emissions in novel combustion systems: development of numerical models.
Dipartimento
INGEGNERIA DELL'ENERGIA, DEI SISTEMI, DEL TERRITORIO E DELLE COSTRUZIONI
Corso di studi
INGEGNERIA ENERGETICA
Relatori
relatore Prof. Tognotti, Leonardo
relatore Ing. Galletti, Chiara
relatore Prof. Parente, Alessandro
relatore Ing. Galletti, Chiara
relatore Prof. Parente, Alessandro
Parole chiave
- CFD
- JHC burner
- MILD combustion
- NOx
- Numerical model
- Pilote-scale burner
- Pollutant emissions
Data inizio appello
05/05/2014
Consultabilità
Completa
Riassunto
The work is focused on the development of comprehensive models for NOx formation in systems operating in MILD combustion (also known as flameless combustion). Such novel technology is based on a flame dilution, achieved through recirculation of combustion products in the reaction region. MILD combustion ensures high combustion efficiency with low NOx emissions and it is promising for low-calorific fuels, industrial wastes as well as in presence of H2.
Because of the low temperature conditions, the thermal NO formation becomes less significant; hence other routes, such as N2O/NO and NNH route should be taken into account. The latter could be important in presence of H2.
The present thesis is motivated by the need to revise existing NO models to be incorporated in CFD tools for conditions typical of MILD combustion.
A new reduced NO model (including thermal, prompt, N2O and NNH pathways) is derived and tested for a Jet in Hot Coflow burner fed with CH4/H2, fully characterised in literature and emulating MILD combustion.
Subsequently, another model is derived and applied to a NG-fired pilot-scale burner, whose experiments were performed by also injecting an ammonia solution. Large attention is paid also to the development of the burner CFD model.
Because of the low temperature conditions, the thermal NO formation becomes less significant; hence other routes, such as N2O/NO and NNH route should be taken into account. The latter could be important in presence of H2.
The present thesis is motivated by the need to revise existing NO models to be incorporated in CFD tools for conditions typical of MILD combustion.
A new reduced NO model (including thermal, prompt, N2O and NNH pathways) is derived and tested for a Jet in Hot Coflow burner fed with CH4/H2, fully characterised in literature and emulating MILD combustion.
Subsequently, another model is derived and applied to a NG-fired pilot-scale burner, whose experiments were performed by also injecting an ammonia solution. Large attention is paid also to the development of the burner CFD model.
File
Nome file | Dimensione |
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Appendix.pdf | 2.58 Mb |
Bibliography.pdf | 632.65 Kb |
Chapter1.pdf | 9.43 Mb |
Chapter2.pdf | 5.60 Mb |
Chapter3.pdf | 22.09 Mb |
Conclusion.pdf | 511.96 Kb |
Contents.pdf | 530.71 Kb |
Frontespizio.pdf | 129.93 Kb |
Introduction.pdf | 487.20 Kb |
List_Fig...ables.pdf | 1.05 Mb |
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