Research Article
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Year 2019, , 57 - 64, 16.09.2019
https://doi.org/10.31593/ijeat.518973

Abstract

References

  • [1] Obaidullah M. Particle Emissions from Small Scale Combustion Appliances. Brussel, Belgium: Vrije Universiteit Brussel (VUB); PhD thesis, November 2014.
  • [2] Obaidullah M, Bram S, Verma V, De Ruyck J. A Review on Particle Emissions from Small Scale Biomass Combustion. International Journal of Renewable Energy Research (IJRER). 2012;2:147-59.
  • [3] Obaidullah M, Bram S, De Ruyck J. Characteristics of Particle Mass Concentrations from Small Scale Biomass Combustion: A Review. VII International Conference on Energy and Environment for 21 Century. Las Villas, Cuba: Central University Marta Abreu (UCLV); 2012.
  • [4] Sippula O, Hokkinen J, Puustinen H, Yli-Pirila P, Jokiniemi J. Comparison of particle emissions from small heavy fuel oil and wood-fired boilers. Atmospheric Environment. 2009;43:4855-64.
  • [5] Obaidullah M, Bram S, De Ruyck J. Investigation on Gaseous and Particle Mass Emissions from Automatically Fired Small Scale Heating System Under Laboratory Conditions. International Journal of Renewable Energy Development. 2018;7:111-21.
  • [6] Obaidullah M, Bram S, De Ruyck J. An Overview of PM Formation Mechanisms from Residential Biomass Combustion and Instruments Using in PM Measurements. International Journal of Energy and Environment. 2018;12:41-50.
  • [7] Obernberger I, Brunner T, Barnthaler G. Fine particle emissions from Modern Austrian small scale biomass combustion plants. 15th European biomass conference and exhibition. Germany7-11 May 2007. p. 1546-57.
  • [8] Boman C, Nordin A, Bostrom D, Ohman M. Characterization of Inorganic Particulate Matter from Residential Combustion of Pelletized Biomass Fuels. Energy & Fuels. 2004;18:338-48.
  • [9] Bäfver LS, Leckner B, Tullin C, Berntsen M. Particle emissions from pellets stoves and modern and old-type wood stoves. Biomass and Bioenergy. 2011;35:3648-55. [10] Qiu G. Testing of flue gas emissions of a biomass pellet boiler and abatement of particle emissions. Renewable Energy. 2013;50:94-102.
  • [11] Stuv SA. Stuv installation instructions. 97851. Belgium 2011. p. 7.
  • [12] EN-13229. Open fires and inserts solid fuel - Requirements and test methods. French Association Standardization; June 2002.
  • [13] Obaidullah M, Sarkar M, Bram S, De Ruyck J. Evaluation of Dilution Ratio from a Partial flow Dilution Tunnel. 7th IMEC &16th Annual Paper Meet. IEB, Dhaka2-3 Jan 2015.
  • [14] Obaidullah M, Bram S, De Ruyck J. Investigation of Optimal Dilution Ratio from a Dilution Tunnel Using in Particulate Matter Measurement. International Journal of Engineering Technology and Sciences (IJETS). 2018;5:17-33.
  • [15] Kubica K, Paradiz B, Dilara P. Small combustion installation: Techniques, emissions and measure for emissions reduction. JRC Scientific and Technical Reports2007.
  • [16] Lighty JS, Veranth JM, Sarofim AF. Combustion Aerosols: Factors Governing Their Size and Composition and Implications to Human Health. Journal of the Air & Waste Management Association: Taylor & Francis; 2000. p. 1565-618.
  • [17] Nussbaumer T, Klippel N, Johansson L. Survey on measurements and emission factors on particulate matter from biomass combustion in IEA countries. Proc 16 th European Biomass Conference and Exhibition2008. p. 2-6.
  • [18] Obaidullah M, Dyakov I, Peeters L, Bram S, De Ruyck J. Comparison of particle emissions from enclosed parking garages and streets. GNEST. 2013;15:457-65.
  • [19] Bolling AK, Pagels J, Yttri KE, Barregard L, Sallsten G, Schwarze PE, et al. Health effects of residential wood smoke particles: the importance of combustion conditions and physicochemical particle properties. Particle and fibre toxicology. 2009;6:20.
  • [20] Obaidullah M, Dyakov I, Peeters L, Bram S, De Ruyck J. Investigation of Particulate Matter Pollutants in Parking Garages. In: Mastorakis N, editor. Latest advancement in Biology, Environment and Ecology. G. Enescu University, Iasi, Romania: WSEAS and NAUN Press; 2012. p. 105-10.
  • [21] Obaidullah M, Dyakov I, Peeters L, Bram S, De Ruyck J. Measurements of Particle Concentrations and Size Distributions in Three Parking Garages. International journal of energy and environment. 2012;6:508-15.
  • [22] Sippula O. Fine particle formation and emission in biomass combustion [Ph. D]. Finland: University of Eastern Finland; 2010.
  • [23] Obaidullah M, Bram S, De Ruyck J. Measurements of Particle Emissions and Size Distributions from a Modern Residential Pellet Stove under Laboratory Conditions. International Journal of Systems Applications, Engineering & Development 2019;13:1-9.
  • [24] Royal-Decree, Belgium. Regulating the minimum efficiency requirements and emission levels of pollutants heaters with solid fuels. October 2010, (available at http://environnement.wallonie.be/legis/air/air064.htm ).
  • [25] Roy MM, Corscadden KW. An experimental study of combustion and emissions of biomass briquettes in a domestic wood stove. Applied Energy. 2012;99:206-12.
  • [26] Obaidullah M, Bram S, Thomassin JD, Duquesne T, Dyakov IV, Contino F, et al. CO Emission Measurements and Performance Analysis of 10 kW and 20 kW Wood Stoves. Energy Procedia. 2014;61:2301-6.
  • [27] Pettersson Er, Boman C, Westerholm R, Bostrom D, Nordin A. Stove Performance and Emission Characteristics in Residential Wood Log and Pellet Combustion, Part 2: Wood Stove. Energy & Fuels. 2011;25:315-23.
  • [28] Schmidl C, Luisser M, Padouvas E, Lasselsberger L, Rzaca M, Ramirez-Santa Cruz C, et al. Particulate and gaseous emissions from manually and automatically fired small scale combustion systems. Atmospheric Environment. 2011;45:7443-54.
  • [29] Koyuncu T, Pinar Y. The emissions from a space-heating biomass stove. Biomass and Bioenergy. 2007;31:73-9.
  • [30] Hukkanen A, Kaivosoja T, Sippula O, Nuutinen K, Jokiniemi J, Tissari J. Reduction of gaseous and particulate emissions from small-scale wood combustion with a catalytic combustor. Atmospheric Environment. 2012.

Particle mass and gaseous emissions from small scale modern wood stoves

Year 2019, , 57 - 64, 16.09.2019
https://doi.org/10.31593/ijeat.518973

Abstract

The objectives of the paper were to evaluate
particle mass concentrations of PM1 (size <1 µm) and PM2.5
(size <2.5 µm), mass size distributions and CO emissions under standard
laboratory conditions obtained from two commercially available modern
residential wood stoves with capacity 10 kW and 20 kW. Four combustion batches
with minor modification of primary air flows into the combustion chamber for
each stove were conducted to evaluate the emission results. Particle mass
concentrations and size distributions were measured in real time using an
Electrical Low Pressure Impactor Plus (ELPI+) instrument, which measures
particles with a fast response time in a wide particle size range from 6 nm to
10 µm aerodynamic diameter. Gaseous concentrations of O2 and CO2
were measured continuously using a Horiba PG-250 analyzer and CO emissions were
measured using a Siemens Ultramat 6 gas analyzer. The measurement protocols of
each combustion test were conducted according to the European standard EN
13229. The combustion experiments were conducted in a laboratory of a stove
manufacturing plant in Belgium. The results showed that PM1 and PM2.5
concentrations of all the batches of both stoves varied from 116 to 327 mg/Nm3
and 139 to 413 mg/Nm3, respectively in the combustion cycle.
Particle mass size distribution for all batches from both stoves is very
similar showing a maximum in the fine mode at a particle size of around
330 nm to 500 nm. The CO emissions from all the batches varied from
447 to 1184 mg/Nm3 for the 10 kW stove and 958 to 1545 mg/Nm3
for the 20 kW stove. The experimental results of PM1, PM2.5
concentrations and CO emissions from combustion measurements could be useful
for the improvement of the combustion process as well as the reduction of
gaseous and particle mass emissions from these residential biomass combustion
appliances.

References

  • [1] Obaidullah M. Particle Emissions from Small Scale Combustion Appliances. Brussel, Belgium: Vrije Universiteit Brussel (VUB); PhD thesis, November 2014.
  • [2] Obaidullah M, Bram S, Verma V, De Ruyck J. A Review on Particle Emissions from Small Scale Biomass Combustion. International Journal of Renewable Energy Research (IJRER). 2012;2:147-59.
  • [3] Obaidullah M, Bram S, De Ruyck J. Characteristics of Particle Mass Concentrations from Small Scale Biomass Combustion: A Review. VII International Conference on Energy and Environment for 21 Century. Las Villas, Cuba: Central University Marta Abreu (UCLV); 2012.
  • [4] Sippula O, Hokkinen J, Puustinen H, Yli-Pirila P, Jokiniemi J. Comparison of particle emissions from small heavy fuel oil and wood-fired boilers. Atmospheric Environment. 2009;43:4855-64.
  • [5] Obaidullah M, Bram S, De Ruyck J. Investigation on Gaseous and Particle Mass Emissions from Automatically Fired Small Scale Heating System Under Laboratory Conditions. International Journal of Renewable Energy Development. 2018;7:111-21.
  • [6] Obaidullah M, Bram S, De Ruyck J. An Overview of PM Formation Mechanisms from Residential Biomass Combustion and Instruments Using in PM Measurements. International Journal of Energy and Environment. 2018;12:41-50.
  • [7] Obernberger I, Brunner T, Barnthaler G. Fine particle emissions from Modern Austrian small scale biomass combustion plants. 15th European biomass conference and exhibition. Germany7-11 May 2007. p. 1546-57.
  • [8] Boman C, Nordin A, Bostrom D, Ohman M. Characterization of Inorganic Particulate Matter from Residential Combustion of Pelletized Biomass Fuels. Energy & Fuels. 2004;18:338-48.
  • [9] Bäfver LS, Leckner B, Tullin C, Berntsen M. Particle emissions from pellets stoves and modern and old-type wood stoves. Biomass and Bioenergy. 2011;35:3648-55. [10] Qiu G. Testing of flue gas emissions of a biomass pellet boiler and abatement of particle emissions. Renewable Energy. 2013;50:94-102.
  • [11] Stuv SA. Stuv installation instructions. 97851. Belgium 2011. p. 7.
  • [12] EN-13229. Open fires and inserts solid fuel - Requirements and test methods. French Association Standardization; June 2002.
  • [13] Obaidullah M, Sarkar M, Bram S, De Ruyck J. Evaluation of Dilution Ratio from a Partial flow Dilution Tunnel. 7th IMEC &16th Annual Paper Meet. IEB, Dhaka2-3 Jan 2015.
  • [14] Obaidullah M, Bram S, De Ruyck J. Investigation of Optimal Dilution Ratio from a Dilution Tunnel Using in Particulate Matter Measurement. International Journal of Engineering Technology and Sciences (IJETS). 2018;5:17-33.
  • [15] Kubica K, Paradiz B, Dilara P. Small combustion installation: Techniques, emissions and measure for emissions reduction. JRC Scientific and Technical Reports2007.
  • [16] Lighty JS, Veranth JM, Sarofim AF. Combustion Aerosols: Factors Governing Their Size and Composition and Implications to Human Health. Journal of the Air & Waste Management Association: Taylor & Francis; 2000. p. 1565-618.
  • [17] Nussbaumer T, Klippel N, Johansson L. Survey on measurements and emission factors on particulate matter from biomass combustion in IEA countries. Proc 16 th European Biomass Conference and Exhibition2008. p. 2-6.
  • [18] Obaidullah M, Dyakov I, Peeters L, Bram S, De Ruyck J. Comparison of particle emissions from enclosed parking garages and streets. GNEST. 2013;15:457-65.
  • [19] Bolling AK, Pagels J, Yttri KE, Barregard L, Sallsten G, Schwarze PE, et al. Health effects of residential wood smoke particles: the importance of combustion conditions and physicochemical particle properties. Particle and fibre toxicology. 2009;6:20.
  • [20] Obaidullah M, Dyakov I, Peeters L, Bram S, De Ruyck J. Investigation of Particulate Matter Pollutants in Parking Garages. In: Mastorakis N, editor. Latest advancement in Biology, Environment and Ecology. G. Enescu University, Iasi, Romania: WSEAS and NAUN Press; 2012. p. 105-10.
  • [21] Obaidullah M, Dyakov I, Peeters L, Bram S, De Ruyck J. Measurements of Particle Concentrations and Size Distributions in Three Parking Garages. International journal of energy and environment. 2012;6:508-15.
  • [22] Sippula O. Fine particle formation and emission in biomass combustion [Ph. D]. Finland: University of Eastern Finland; 2010.
  • [23] Obaidullah M, Bram S, De Ruyck J. Measurements of Particle Emissions and Size Distributions from a Modern Residential Pellet Stove under Laboratory Conditions. International Journal of Systems Applications, Engineering & Development 2019;13:1-9.
  • [24] Royal-Decree, Belgium. Regulating the minimum efficiency requirements and emission levels of pollutants heaters with solid fuels. October 2010, (available at http://environnement.wallonie.be/legis/air/air064.htm ).
  • [25] Roy MM, Corscadden KW. An experimental study of combustion and emissions of biomass briquettes in a domestic wood stove. Applied Energy. 2012;99:206-12.
  • [26] Obaidullah M, Bram S, Thomassin JD, Duquesne T, Dyakov IV, Contino F, et al. CO Emission Measurements and Performance Analysis of 10 kW and 20 kW Wood Stoves. Energy Procedia. 2014;61:2301-6.
  • [27] Pettersson Er, Boman C, Westerholm R, Bostrom D, Nordin A. Stove Performance and Emission Characteristics in Residential Wood Log and Pellet Combustion, Part 2: Wood Stove. Energy & Fuels. 2011;25:315-23.
  • [28] Schmidl C, Luisser M, Padouvas E, Lasselsberger L, Rzaca M, Ramirez-Santa Cruz C, et al. Particulate and gaseous emissions from manually and automatically fired small scale combustion systems. Atmospheric Environment. 2011;45:7443-54.
  • [29] Koyuncu T, Pinar Y. The emissions from a space-heating biomass stove. Biomass and Bioenergy. 2007;31:73-9.
  • [30] Hukkanen A, Kaivosoja T, Sippula O, Nuutinen K, Jokiniemi J, Tissari J. Reduction of gaseous and particulate emissions from small-scale wood combustion with a catalytic combustor. Atmospheric Environment. 2012.
There are 29 citations in total.

Details

Primary Language English
Journal Section Research Article
Authors

Md. Obaidullah 0000-0001-7086-9789

Publication Date September 16, 2019
Submission Date January 29, 2019
Acceptance Date May 27, 2019
Published in Issue Year 2019

Cite

APA Obaidullah, M. (2019). Particle mass and gaseous emissions from small scale modern wood stoves. International Journal of Energy Applications and Technologies, 6(2), 57-64. https://doi.org/10.31593/ijeat.518973
AMA Obaidullah M. Particle mass and gaseous emissions from small scale modern wood stoves. IJEAT. September 2019;6(2):57-64. doi:10.31593/ijeat.518973
Chicago Obaidullah, Md. “Particle Mass and Gaseous Emissions from Small Scale Modern Wood Stoves”. International Journal of Energy Applications and Technologies 6, no. 2 (September 2019): 57-64. https://doi.org/10.31593/ijeat.518973.
EndNote Obaidullah M (September 1, 2019) Particle mass and gaseous emissions from small scale modern wood stoves. International Journal of Energy Applications and Technologies 6 2 57–64.
IEEE M. Obaidullah, “Particle mass and gaseous emissions from small scale modern wood stoves”, IJEAT, vol. 6, no. 2, pp. 57–64, 2019, doi: 10.31593/ijeat.518973.
ISNAD Obaidullah, Md. “Particle Mass and Gaseous Emissions from Small Scale Modern Wood Stoves”. International Journal of Energy Applications and Technologies 6/2 (September 2019), 57-64. https://doi.org/10.31593/ijeat.518973.
JAMA Obaidullah M. Particle mass and gaseous emissions from small scale modern wood stoves. IJEAT. 2019;6:57–64.
MLA Obaidullah, Md. “Particle Mass and Gaseous Emissions from Small Scale Modern Wood Stoves”. International Journal of Energy Applications and Technologies, vol. 6, no. 2, 2019, pp. 57-64, doi:10.31593/ijeat.518973.
Vancouver Obaidullah M. Particle mass and gaseous emissions from small scale modern wood stoves. IJEAT. 2019;6(2):57-64.

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