Gaseous and Solid Air Pollutants Formed during the Combustion of Heavy Metal Contaminated Oak and Poplar

Helga Kovacs; Katalin Szemmelveisz; Alex Nemes

doi:10.4028/www.scientific.net/AMR.875-877.743

Paper Titles

Experimental Analysis of the Welded Joint Temperature Field
p.720

A Novel Wild-Land Fire-Fighting Foam for Minimizing the Phytotoxicity of Wood Burning-Derived Smoke Tested in Living Plant Cells
p.725

NMOS Low Boron Activation in Pre-Amorphise Silicon
p.734

Study on Dust-Removing Characteristic of Carbon Fiber Membrane in Electrostatic Precipitator
p.739

Gaseous and Solid Air Pollutants Formed during the Combustion of Heavy Metal Contaminated Oak and Poplar
p.743

Rapid Detection and Quantification of Lanthanide Ions Using High-Speed Polymerase Chain Reactions
p.749

Buckling Analysis of Advanced Grid Stiffened Composite Cylinders
p.755

Application of RCW Base Dissipator on a Set of Masonry Buildings
p.763

Estimation of a Nusselt Correlations for Numerical Prediction of Frost Thickness Growth over a Cold Cylinder
p.771

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 875-877Gaseous and Solid Air Pollutants Formed during the...

Gaseous and Solid Air Pollutants Formed during the Combustion of Heavy Metal Contaminated Oak and Poplar

Abstract:

In recent decades several industrial activities polluted the soil, which caused the accumulation of heavy metals to an extent greater than the natural concentration. This is mainly typical of countries, where mining and industry plays or has played an important role in the economy. The utilization of these lands is an economic interest, since locating the contamination, controlling its spreading and maintaining the area has costs. One of the methods for remediation is phytoextraction, during which heavy metals, especially harmful to water and soil, are removed from the soil by plants capable of accumulating contaminants. However, during the combustion of these plants their heavy metal content is replaced into the formed gaseous and solid combustion remains, so the hazard, composition and treating method of these remains must be defined by the appropriate examinations. In this article we present some part of the results of this research, where we examine the gaseous and solid pollutant content of flue gas formed during combustion, as well as the heavy metal content of fly ash. We made two different experiments for domestic and semiplant usage. We have used oak and poplar from a heavy metal contaminated area in both experiments. The domestic examination was conducted in a 7 kW hearth with a closed combustion chamber, the semiplant examination was carried out in a 0,5 MW capacity furnace equipped with an automatic fuel feeding system and a cyclone dust extractor. We have measured the composition of flue gas in both firing experiments with a HORIBA PG-250 type portable gas analyzer, in the case of the analysis of heavy metal content of fly ash DX4 EDAX EDS microprobe of an AMRAY 1830 I scanning electron microscope and ICP-AES, using a 720 ES instrument was used. Based on our results, it can be determined, that the combustion device used to burn biomass grown on heavy metal polluted areas – brownfield lands – must make it possible to separate fly ash from the flue gas and allow the handling of solid burning residues.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 875-877)

Pages:

743-748

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.875-877.743

Citation:

Cite this paper

Online since:

February 2014

Authors:

Helga Kovacs, Katalin Szemmelveisz, Alex Nemes

Keywords:

Brownfield Lands, Combustion Experiments, Heavy Metal Pollution, Ligneous Plants

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Chhotu D. Jadia and M. H. Fulekar: Phytoremediation of heavy metals: Recent techniques, African Journal of Biotechnology Vol. 8 (6), pp.921-928, 20 March, 2009, ISSN 1684–5315 © 2009 Academic Journal.

Google Scholar

[2] Barótfi István: Környezettechnika, Mezőgazda Kiadó Kft., 2002, ISBN 9632860098.

Google Scholar

[3] Anton Attila, Murányi Attila: Hatékony fitoremediáció, MOKKA Konferencia, Budapest, 2007. június 15., in http: /enfo. hu/mokka/conference/Hungarian_Presentations/Anton_Muranyi_ppt. pdf.

Google Scholar

[4] Mary B. Ogundiran* and Oladele Osibanjo: Heavy metal concentrations in soils and accumulation in plants growing in a deserted slag dumpsite in Nigeria, African Journal of Biotechnology Vol. 7 (17), pp.3053-3060.

Google Scholar

[5] Tariq Mahmood, K.R. Islam, S. Muhammad: toxic effects of heavy metals on early growth and tolerance of cereal crops, Pak. J. Bot., 39(2): 451-462, (2007).

Google Scholar

[6] MSZ 21456/5-86 86Examination of gaseous air pollutants. Determining carbon monoxide.

Google Scholar

[7] MSZ 21853/19-81 Examination of air pollutant sources.

Google Scholar

[8] MSZ 21853/6-84 Examination of air pollutant sources. Determining sulphur dioxide emission. Conductimetric, infrared, ultraviolet method.

Google Scholar

[9] MSZ ISO 7996: 1993 Ambient air. Determining the mass concentration of nitrogen oxides. Chemiluminescence method.

Google Scholar

[10] MSZ 21453: 1988 A specifications on determining solid air pollutants.

Google Scholar

[11] MSZ 21456-37: 1992 Examination of gaseous air pollutants. Sulphur dioxide.

Google Scholar

[12] Hungarian government decree on the technological emission boundary values of air pollutants (140 kWth or -50 MWth) in Hungarian 23/2001. (XI. 13) KöM rendelet: a 140 kWth és az ennél nagyobb, de 50 MWth-nál kisebb névleges bemenő hőteljesítményű tüzelőberendezések légszennyező anyagainak technológiai kibocsátási határértékeiről.

Google Scholar

[13] Hungarian government decree on the technological emission boundary values of air pollutants (>50 MWth) in Hungarian 10/2003. (VII. 11) KVVM rendelet: az 50 MWth és az annál nagyobb névleges bemenő hőteljesítményű tüzelőberendezések működési feltételeiről és légszennyező anyagainak technológiai kibocsátási határértékeiről.

Google Scholar