Experimental investigation of N2O formation in selective non-catalytic NOx reduction processes performed in stoker boiler

Author:

Krawczyk Piotr1

Affiliation:

1. Warsaw University of Technology, Institute of Heat Engineering, 21/25 Nowowiejska Str., 00-665 Warszawa, Poland

Abstract

Abstract Stoker fired boiler plants are common throughout Eastern Europe. Increasingly strict emission standards will require application of secondary NOx abatement systems on such boilers. Yet operation of such systems, in addition to reducing NOx emissions, may also lead to emission of undesirable substances, for example N2O. This paper presents results of experimental tests concerning N2O formation in the selective non-catalytic NOx emission reduction process (SNCR) in a stoker boiler (WR 25 type). Obtained results lead to an unambiguous conclusion that there is a dependency between the NOx and N2O concentrations in the exhaust gas when SNCR process is carried out in a coal-fired stoker boiler. Fulfilling new emission standards in the analysed equipment will require 40–50% reduction of NOx concentration. It should be expected that in such a case the N2O emission will be approximately 55–60 mg/m3, with the NOx to N2O conversion factor of about 40%.

Publisher

Walter de Gruyter GmbH

Subject

General Chemical Engineering,General Chemistry,Biotechnology

Reference21 articles.

1. 1. Wrzesińska, B., Krzywda, R., Wąsowski, T., Krawczyk, P. & Badyda, K. (2015). Technologia selektywnej niekatalitycznej redukcji tlenków azotu pod kątem zastosowania jej w kotłach dla energetyki przemysłowej i ciepłownictwa (A selective non-catalytic reduction of nitrogen oxides technology for application in industrial and municipal heating boilers). Przem. Chem. 94(4) 608–613. DOI: 10.15199/62.2015.4.22 (in Polish).

2. 2. Directive 2010/75/EU of the European Parliament and of the Council of 24 November 2010 on industrial emissions (integrated pollution prevention and control), OJ L 334/17.

3. 3. Regulation of the Minister of Environment of 4 November 2014 on emission standards for certain types of plants, fuel combustion sources.

4. 4. Badyda, K. & Lewandowski, J. (2009). Uwarunkowania wzrostu zapotrzebowania na gaz dla energetyki i ciepłownictwa [Determinants of growth in demand for gas for power and heat generation]. Rynek Energ. 5(84) (in Polish).

5. 5. Krawczyk, P. & Badyda, K. (2014). Numerical analysis of the impact of parameters of urea solution injection on reagent penetration inside the combustion chamber of a WR 25 boiler. Rynek Energ. 6, 115–139.

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