BibTex RIS Kaynak Göster

Flameless Oxidation as a Means to Reduce NOx Emissions in Glass Melting Furnaces

Yıl 2013, Cilt: 16 Sayı: 2, 55 - 61, 01.06.2013

Jörg Leicher

Öz

In the glass industry, very high process temperatures are required in order to melt the raw materials. These temperature levels are usually achieved by burning natural gas with strongly pre-heated air. However, this creates ideal conditions for a strong formation of nitrous oxides (NOX), a pollutant whose emissions are strictly regulated. The industry is therefore very much interested in technologies to suppress the production of NOX within the furnace itself. One possible approach is the so-called flameless oxidation, a novel combustion regime which is characterized by very homogeneous temperature distributions and low NOX production. While this form of combustion is firmly established in the steel industry, the glass industry has been reluctant to change its production methods as the glass melt is very sensitive to changes in the furnace conditions.
Gas- und Wärme-Institut Essen e.V. (GWI), in cooperation with its partners, investigated how to best introduce flameless oxidation into glass melting furnaces. Using both simulation and experimental techniques, a GlasFLOX burner was developed and then examined with regards to its NOX reduction performance. In a second step, the retrofitting of an operating furnace was carried out, based on a strategy determined by extensive CFD simulations.
After five years of operation, the operators of the retrofitted plant report unchanged product quality, while NOX emissions have been reduced by about 50 %.

Anahtar Kelimeler

Glass; NOx Emissions; Flameless oxidation

Kaynakça

  • Flamme, M., Kösters, M., Scherello, A., Kremer, H. & Boß, M. (2000). Experimental Study of Heat Transfer Intensification in Glass Melting Furnaces. Final report of task 2 of the EURONITE project
  • (JOE3CT970083). Gas- und Wärme-Institut Essen e.V., Germany.
  • Giese, A., Konold, U., al-Halbouni, A. Görner, K., Schwarz, G., & Köster, B. (2008). Application of Flameless Oxidation in Glass Melting Furnaces, 7th International Symposium on High Temperature Air Combustion and Gasification, Phuket, Thailand.
  • Jones, W.P., Lindstedt, R.P. (1988). Global reaction mechanisms for hydrocarbon combustion, Comb. & Flame. 73(3), 233-249.
  • Milani, A. (2000). “Mild Combustion” techniques applied to regenerative firing in industrial furnaces, 2 nd International Seminar on High Temperature Combustion, Stockholm, Sweden.
  • Scherello, A.; Konold, U., & Görner, K. (2007). Anwendung der flammenlosen Oxidation für Glasschmelzwannen mit rekuperativer Luftvorwärmung – GlasFLOX®, 23. Deutscher Flammentag, 12.-13. September 2007, Berlin, Germany, VDI-Bericht 1988.
  • Wünning, J. G. (1996). Flammlose Oxidation von Brennstoff. PhD Thesis. RWTH Aachen, Germany.
  • Wünning, J. G. (2003). FLOX-Flameless Combustion. Thermprocess Symposium. Düsseldorf, Germany.

Yıl 2013, Cilt: 16 Sayı: 2, 55 - 61, 01.06.2013

Jörg Leicher

Öz

Kaynakça

  • Flamme, M., Kösters, M., Scherello, A., Kremer, H. & Boß, M. (2000). Experimental Study of Heat Transfer Intensification in Glass Melting Furnaces. Final report of task 2 of the EURONITE project
  • (JOE3CT970083). Gas- und Wärme-Institut Essen e.V., Germany.
  • Giese, A., Konold, U., al-Halbouni, A. Görner, K., Schwarz, G., & Köster, B. (2008). Application of Flameless Oxidation in Glass Melting Furnaces, 7th International Symposium on High Temperature Air Combustion and Gasification, Phuket, Thailand.
  • Jones, W.P., Lindstedt, R.P. (1988). Global reaction mechanisms for hydrocarbon combustion, Comb. & Flame. 73(3), 233-249.
  • Milani, A. (2000). “Mild Combustion” techniques applied to regenerative firing in industrial furnaces, 2 nd International Seminar on High Temperature Combustion, Stockholm, Sweden.
  • Scherello, A.; Konold, U., & Görner, K. (2007). Anwendung der flammenlosen Oxidation für Glasschmelzwannen mit rekuperativer Luftvorwärmung – GlasFLOX®, 23. Deutscher Flammentag, 12.-13. September 2007, Berlin, Germany, VDI-Bericht 1988.
  • Wünning, J. G. (1996). Flammlose Oxidation von Brennstoff. PhD Thesis. RWTH Aachen, Germany.
  • Wünning, J. G. (2003). FLOX-Flameless Combustion. Thermprocess Symposium. Düsseldorf, Germany.
Toplam 8 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Bölüm Invited ECOS 2011 Paper for ECOS Special Issue
Yazarlar

Jörg Leicher

Yayımlanma Tarihi 1 Haziran 2013
Yayımlandığı Sayı Yıl 2013 Cilt: 16 Sayı: 2

Kaynak Göster

APA Leicher, J. (2013). Flameless Oxidation as a Means to Reduce NOx Emissions in Glass Melting Furnaces. International Journal of Thermodynamics, 16(2), 55-61.
AMA Leicher J. Flameless Oxidation as a Means to Reduce NOx Emissions in Glass Melting Furnaces. International Journal of Thermodynamics. Haziran 2013;16(2):55-61.
Chicago Leicher, Jörg. “Flameless Oxidation As a Means to Reduce NOx Emissions in Glass Melting Furnaces”. International Journal of Thermodynamics 16, sy. 2 (Haziran 2013): 55-61.
EndNote Leicher J (01 Haziran 2013) Flameless Oxidation as a Means to Reduce NOx Emissions in Glass Melting Furnaces. International Journal of Thermodynamics 16 2 55–61.
IEEE J. Leicher, “Flameless Oxidation as a Means to Reduce NOx Emissions in Glass Melting Furnaces”, International Journal of Thermodynamics, c. 16, sy. 2, ss. 55–61, 2013.
ISNAD Leicher, Jörg. “Flameless Oxidation As a Means to Reduce NOx Emissions in Glass Melting Furnaces”. International Journal of Thermodynamics 16/2 (Haziran 2013), 55-61.
JAMA Leicher J. Flameless Oxidation as a Means to Reduce NOx Emissions in Glass Melting Furnaces. International Journal of Thermodynamics. 2013;16:55–61.
MLA Leicher, Jörg. “Flameless Oxidation As a Means to Reduce NOx Emissions in Glass Melting Furnaces”. International Journal of Thermodynamics, c. 16, sy. 2, 2013, ss. 55-61.
Vancouver Leicher J. Flameless Oxidation as a Means to Reduce NOx Emissions in Glass Melting Furnaces. International Journal of Thermodynamics. 2013;16(2):55-61.