Experimental and numerical analysis of fine particle and soot formation in a modern 100 MW pulverized biomass heating plant

Niko P. Niemelä; Fanni Mylläri; Niina Kuittinen; Minna Aurela; Aku Helin; Joel Kuula; Kimmo Teinilä; Markus Nikka; Oskari Vainio; Anssi Arffman; Henna Lintusaari; Hilkka Timonen; Topi Rönkkö; Tero Joronen

doi:10.1016/j.combustflame.2021.111960

Experimental and numerical analysis of fine particle and soot formation in a modern 100 MW pulverized biomass heating plant

Niko P. Niemelä, Fanni Mylläri, Niina Kuittinen, Minna Aurela, Aku Helin, Joel Kuula, Kimmo Teinilä, Markus Nikka, Oskari Vainio, Anssi Arffman, Henna Lintusaari, Hilkka Timonen, Topi Rönkkö, Tero Joronen

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Abstract

The formation of soot, organic, and inorganic aerosols has a profound effect on the environmental and technological feasibility of biomass combustion. In this work, the soot and aerosol processes are examined for a modern pulverized wood-burning 100 MW_th district heating plant. Experimental data was collected from two locations inside the furnace (30% and 100% thermal loads), including measurements for fine particle (PM₁) number size distribution, number concentration, and chemical composition. The experiments were complemented with Computational Fluid Dynamics (CFD) simulations and Plug-Flow Reactor (PFR) modeling. The measurements and modeling are combined in a comprehensive analysis, providing fundamental understanding on the aerosol processes inside the furnace. The wood-powder combustion is efficient under both thermal loads, indicated by the low unburned carbon content in fly-ash, and the low CO, NO and soot emissions (<0.3 mg/Nm³). The fine particles consist mainly of K₂SO₄, and of lesser amounts of alkali salts (NaCl, KCl), and Ca and Mg compounds (oxides or sulfates). A large concentration of KOH/K₂CO₃ vapor may exist in the flue gas and play a significant role in the heat exchanger fouling. The applied modeling tools are shown to provide accurate estimations for the composition and formation regions of fine particles inside the industrial biomass furnaces.

Original language	English
Article number	111960
Number of pages	14
Journal	Combustion and Flame
Volume	240
DOIs	https://doi.org/10.1016/j.combustflame.2021.111960
Publication status	Published - 2022
Publication type	A1 Journal article-refereed

Keywords

Biomass
Combustion
Fine particles
Fouling
Pulverized fuel
Soot

Publication forum classification

Publication forum level 3

ASJC Scopus subject areas

General Chemistry
General Chemical Engineering
Fuel Technology
Energy Engineering and Power Technology
General Physics and Astronomy

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.combustflame.2021.111960Licence: CC BY

1-s2.0-S0010218021007033-mainFinal published version, 3.86 MBLicence: CC BY

https://urn.fi/URN:NBN:fi:tuni-202203312917Licence: CC BY

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Niemelä, N. P., Mylläri, F., Kuittinen, N., Aurela, M., Helin, A., Kuula, J., Teinilä, K., Nikka, M., Vainio, O., Arffman, A., Lintusaari, H., Timonen, H., Rönkkö, T., & Joronen, T. (2022). Experimental and numerical analysis of fine particle and soot formation in a modern 100 MW pulverized biomass heating plant. Combustion and Flame, 240, Article 111960. https://doi.org/10.1016/j.combustflame.2021.111960

@article{d9c941356c1248ebb327eaddec201378,

title = "Experimental and numerical analysis of fine particle and soot formation in a modern 100 MW pulverized biomass heating plant",

abstract = "The formation of soot, organic, and inorganic aerosols has a profound effect on the environmental and technological feasibility of biomass combustion. In this work, the soot and aerosol processes are examined for a modern pulverized wood-burning 100 MWth district heating plant. Experimental data was collected from two locations inside the furnace (30% and 100% thermal loads), including measurements for fine particle (PM1) number size distribution, number concentration, and chemical composition. The experiments were complemented with Computational Fluid Dynamics (CFD) simulations and Plug-Flow Reactor (PFR) modeling. The measurements and modeling are combined in a comprehensive analysis, providing fundamental understanding on the aerosol processes inside the furnace. The wood-powder combustion is efficient under both thermal loads, indicated by the low unburned carbon content in fly-ash, and the low CO, NO and soot emissions (<0.3 mg/Nm3). The fine particles consist mainly of K2SO4, and of lesser amounts of alkali salts (NaCl, KCl), and Ca and Mg compounds (oxides or sulfates). A large concentration of KOH/K2CO3 vapor may exist in the flue gas and play a significant role in the heat exchanger fouling. The applied modeling tools are shown to provide accurate estimations for the composition and formation regions of fine particles inside the industrial biomass furnaces.",

keywords = "Biomass, Combustion, Fine particles, Fouling, Pulverized fuel, Soot",

author = "Niemel{\"a}, {Niko P.} and Fanni Myll{\"a}ri and Niina Kuittinen and Minna Aurela and Aku Helin and Joel Kuula and Kimmo Teinil{\"a} and Markus Nikka and Oskari Vainio and Anssi Arffman and Henna Lintusaari and Hilkka Timonen and Topi R{\"o}nkk{\"o} and Tero Joronen",

note = "Funding Information: Teemu Lepist{\"o}, Paavo Heikkil{\"a}, Laura Salo, Lassi Markkula, and Panu Karjalainen are acknowledged for the valuable help in the measurement campaign. Joni Rantanen is acknowledged for his important support in the modeling work. Fanni Myll{\"a}ri is thankful for the personal and project funding provided by the Nessling Foundation. Niko Niemel{\"a} is thankful to Thorben de Riese for the fruitful discussions related to ash chemistry. The BC Footprint project (grant no. 49402–201040) funded by Business Finland, HSY, City of Tampere, and several Finnish companies, as well as the Academy of Finland flagship funding from Atmosphere and Climate Competence Center, ACCC (grant no. 337551, 337552) are gratefully acknowledged. The authors are thankful to Helen Oy and Valmet Oyj for providing the essential process and measurement data for the research. Publisher Copyright: {\textcopyright} 2021",

year = "2022",

doi = "10.1016/j.combustflame.2021.111960",

language = "English",

volume = "240",

journal = "Combustion and Flame",

issn = "0010-2180",

publisher = "Elsevier Inc.",

}

Niemelä, NP, Mylläri, F, Kuittinen, N, Aurela, M, Helin, A, Kuula, J, Teinilä, K, Nikka, M, Vainio, O, Arffman, A, Lintusaari, H, Timonen, H, Rönkkö, T & Joronen, T 2022, 'Experimental and numerical analysis of fine particle and soot formation in a modern 100 MW pulverized biomass heating plant', Combustion and Flame, vol. 240, 111960. https://doi.org/10.1016/j.combustflame.2021.111960

TY - JOUR

T1 - Experimental and numerical analysis of fine particle and soot formation in a modern 100 MW pulverized biomass heating plant

AU - Niemelä, Niko P.

AU - Mylläri, Fanni

AU - Kuittinen, Niina

AU - Aurela, Minna

AU - Helin, Aku

AU - Kuula, Joel

AU - Teinilä, Kimmo

AU - Nikka, Markus

AU - Vainio, Oskari

AU - Arffman, Anssi

AU - Lintusaari, Henna

AU - Timonen, Hilkka

AU - Rönkkö, Topi

AU - Joronen, Tero

N1 - Funding Information: Teemu Lepistö, Paavo Heikkilä, Laura Salo, Lassi Markkula, and Panu Karjalainen are acknowledged for the valuable help in the measurement campaign. Joni Rantanen is acknowledged for his important support in the modeling work. Fanni Mylläri is thankful for the personal and project funding provided by the Nessling Foundation. Niko Niemelä is thankful to Thorben de Riese for the fruitful discussions related to ash chemistry. The BC Footprint project (grant no. 49402–201040) funded by Business Finland, HSY, City of Tampere, and several Finnish companies, as well as the Academy of Finland flagship funding from Atmosphere and Climate Competence Center, ACCC (grant no. 337551, 337552) are gratefully acknowledged. The authors are thankful to Helen Oy and Valmet Oyj for providing the essential process and measurement data for the research. Publisher Copyright: © 2021

PY - 2022

Y1 - 2022

N2 - The formation of soot, organic, and inorganic aerosols has a profound effect on the environmental and technological feasibility of biomass combustion. In this work, the soot and aerosol processes are examined for a modern pulverized wood-burning 100 MWth district heating plant. Experimental data was collected from two locations inside the furnace (30% and 100% thermal loads), including measurements for fine particle (PM1) number size distribution, number concentration, and chemical composition. The experiments were complemented with Computational Fluid Dynamics (CFD) simulations and Plug-Flow Reactor (PFR) modeling. The measurements and modeling are combined in a comprehensive analysis, providing fundamental understanding on the aerosol processes inside the furnace. The wood-powder combustion is efficient under both thermal loads, indicated by the low unburned carbon content in fly-ash, and the low CO, NO and soot emissions (<0.3 mg/Nm3). The fine particles consist mainly of K2SO4, and of lesser amounts of alkali salts (NaCl, KCl), and Ca and Mg compounds (oxides or sulfates). A large concentration of KOH/K2CO3 vapor may exist in the flue gas and play a significant role in the heat exchanger fouling. The applied modeling tools are shown to provide accurate estimations for the composition and formation regions of fine particles inside the industrial biomass furnaces.

AB - The formation of soot, organic, and inorganic aerosols has a profound effect on the environmental and technological feasibility of biomass combustion. In this work, the soot and aerosol processes are examined for a modern pulverized wood-burning 100 MWth district heating plant. Experimental data was collected from two locations inside the furnace (30% and 100% thermal loads), including measurements for fine particle (PM1) number size distribution, number concentration, and chemical composition. The experiments were complemented with Computational Fluid Dynamics (CFD) simulations and Plug-Flow Reactor (PFR) modeling. The measurements and modeling are combined in a comprehensive analysis, providing fundamental understanding on the aerosol processes inside the furnace. The wood-powder combustion is efficient under both thermal loads, indicated by the low unburned carbon content in fly-ash, and the low CO, NO and soot emissions (<0.3 mg/Nm3). The fine particles consist mainly of K2SO4, and of lesser amounts of alkali salts (NaCl, KCl), and Ca and Mg compounds (oxides or sulfates). A large concentration of KOH/K2CO3 vapor may exist in the flue gas and play a significant role in the heat exchanger fouling. The applied modeling tools are shown to provide accurate estimations for the composition and formation regions of fine particles inside the industrial biomass furnaces.

KW - Biomass

KW - Combustion

KW - Fine particles

KW - Fouling

KW - Pulverized fuel

KW - Soot

U2 - 10.1016/j.combustflame.2021.111960

DO - 10.1016/j.combustflame.2021.111960

M3 - Article

AN - SCOPUS:85122622238

SN - 0010-2180

VL - 240

JO - Combustion and Flame

JF - Combustion and Flame

M1 - 111960

ER -

Experimental and numerical analysis of fine particle and soot formation in a modern 100 MW pulverized biomass heating plant

Abstract

Keywords

Publication forum classification

ASJC Scopus subject areas

UN SDGs

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