ODOUR STUDY WITH QUALITATIVE AND QUANTITATIVE RESEARCH METHODS IN VARIOUS DISTRICTS OF RIGA

Authors

  • Evita Mužniece-Treija University of Latvia, Faculty of Geography and Earth Sciences (LV)

DOI:

https://doi.org/10.17770/etr2017vol1.2643

Keywords:

gas analysis, odour, various districts of Riga

Abstract

Different emission sources of odours become increasingly important environmental problem which may have a negative impact on human health and quality of life. Human odour perception may be subjective, however on odour perception threshold is considered to be the odorant concentration where at least half of odour assessor’s group members confirm the existence of odour, and then it is 1 OUE /m3. Nowadays more and more advanced technologies are used to measure odour concentration. Olfactometer Scentroid SM100 allows users to accurately quantify ambient odour concentration in field. Also this equipment allows to collect source samples and analyze odour in a laboratory. Odour study in 2016 and 2017 with field olfactometer Scentroid SM100 and gas analyzer Gasmet DX-4030 in districts of Riga indicates that the highest concentrations of odour are in Bolderaja, Sarkandaugava, Kundzinsala, Mangalsala, Milgravis and Vecmilgravis. Study indicates that the highest odour concentrations, especially among producing companies can reach up to 6-7 odour units (OUE/m3), however gas analyzer Gasmet DX-4030 indicates oil products or carbon dioxide.
Supporting Agencies
The author expresses her gratitude to the State Environmental Service for providing the information and to the State Environmental Service for providing the information and material support

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References

Republic of Latvia Cabinet Regulation No. 724 „Regulations Regarding the Methods for Determination of the Odours Caused by Polluting Activity, as well as the Procedures for Restricting the Spread of such Odours”, 2014. Latvijas Vēstnesis, No. 250 (5310), 16.12.2014., Adopted 25.11.2014.

Bokowa Anna H., 2010. Review of Odour Legislation, Chemical Engineering Transactions, Vol. 23. pp. 31 -36.

Brattoli M., De Gennaro G., De Pinto V., Demarinis Loiotile A., Lovascio S., Penza M., 2011. Odour Detection Methods: Olfactometry and Chemical Sensors. Sensors. Vol. 11, pp. 5290-5322.

Dravnieks A., Masurat T., Richard A. Lamm, 2012. Hedonics of Odors and Odor Descriptors, Journal of the Air Pollution Control Association pp. 752-755.

Sironia S., Eusebioa L., Capellia L., Remondinib M., Del Rossoa R. 2014. Use of an Electronic Nose for Indoor Air Quality Monitoring, Chemical engieneering transactions, Vol. 40, pp. 73 – 78.

Zarra T., Reiser M., Naddeo V., Belgirno V., Kranert M., 2012. A comparative and Critical Evaluation of Sampling Marerials in the Measurement of Odour Concentratin by Dynamic Olfactometry, Chemical engieneering transactions, Vol. 30 (12), pp. 307-312.

Kāla A., Beikulis O., Rubins J. 2015. Practical application of commercial ALPHA M.O.S. E-NOSE for air quality control in Riga. European Network on New Sensing Technologies for Air Pollution Control and Environmental Sustainability

- EuNetAir COST Action TD1105.

Scentroid Model 110C. Operating and maintenance manual. 2012. IDES Canada Inc. Version 1.4.

Scentroid Model 110. Operating and maintenance manual. 2013. IDES Canada Inc. Version 2.0.

Bokowa Anna H., 2012. Ambient Odour Assessment Similarities and Differences, Chemical Engineering Transactions, Vol. 30.

DX-4030 FTIR Gas Analyser Instruction and Operating Manual, 2009. URL: http://pembrokeinstruments.com/_download_pdf_897/_Pembroke-PDF-Downloads/Gasmet-DX4030-Manual-Pembroke.pdf, Viewed: 22.10.2016.

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Published

2017-06-15

How to Cite

[1]
E. Mužniece-Treija, “ODOUR STUDY WITH QUALITATIVE AND QUANTITATIVE RESEARCH METHODS IN VARIOUS DISTRICTS OF RIGA”, ETR, vol. 1, pp. 192–196, Jun. 2017, doi: 10.17770/etr2017vol1.2643.