JARKKO TISSARI
Fine Particle Emissions fromResidential Wood Combustion
JOKAKUOPIO 2008
KUOPION YLIOPISTON JULKAISUJA C. LUONNONTIETEET JA YMPÄRISTÖTIETEET 237KUOPIO UNIVERSITY PUBLICATIONS C. NATURAL AND ENVIRONMENTAL SCIENCES 237
Doctoral dissertation
To be presented by permission of the Faculty of Natural and Environmental Sciences
of the University of Kuopio for public examination in
Auditorium L21, Snellmania building, University of Kuopio
on Friday 3rd October 2008, at 1 p.m.
Department of Environmental ScienceUniversity of Kuopio
Distributor : Kuopio University Library P.O. Box 1627 FI-70211 KUOPIO FINLAND Tel. +358 40 355 3430 Fax +358 17 163 410 http://www.uku.fi/kirjasto/julkaisutoiminta/julkmyyn.html
Series Editors: Professor Pertti Pasanen, Ph.D. Department of Environmental Science
Professor Jari Kaipio, Ph.D. Department of Applied Physics
Author’s address: Department of Environmental Science University of Kuopio P.O. Box 1627 FI-70211 KUOPIO FINLAND Tel. +358 40 355 3237 Fax +358 17 163 229 E-mail : [email protected]
Supervisor : Professor Jorma Jokiniemi, Ph.D. Department of Environmental Science University of Kuopio
Reviewers: Dr. Christoffer Boman, Ph.D. Umeå University Energy Technology and Thermal Process Chemistry Umeå, Sweden
Dr. Joakim Pagels, Ph.D. (tech) Lund University, Faculty of Engineering Ergonomics and Aerosol Technology Lund, Sweden
Opponent: Doc. Annele Virtanen, Ph.D. Tampere University of Technology Institute of Physics Tampere, Finland
ISBN 978-951-27-0975-5ISBN 978-951-27-1090-4 (PDF)ISSN 1235-0486
KopijyväKuopio 2008Finland
Tissari, Jarkko. Fine Particle Emissions From Residential Wood Combustion. KuopioUniversity Publications C. Natural and Environmental Sciences 237. 2008. 63 p.ISBN 9789512709755ISBN 9789512710904 (PDF)ISSN 12350486
Abstract
Residential wood combustion (RWC) appliances have the high probability ofincomplete combustion, producing e.g. fine particles and hazardous organic compounds. Inthis thesis, the fine particle number and mass emissions, particle composition andmorphology, and gas emissions were investigated from the modern (MMH) andconventional masonry heaters (CMH), sauna stoves (SS) and pellet burner. Theinvestigation was based on laboratory and field experiments applying extensive and uniqueparticle sampling methods.
The appliance type, fuel and operational practices were found to affect clearly the fineparticle emissions. In good combustion conditions (e.g. in pellet combustion), the fineparticle mass (PM1) emission factors were low, typically below 0.3 g kg1, and over 90% ofthe PM1 consisted of inorganic compounds (i.e "fine ash"). From the CMH the typical PM1values were 1.6–1.8 g kg1, and from the SS 2.7–5.0 g kg1, but were strongly dependent onoperational practices. The smouldering combustion in CMH increased PM1 emission up to10 g kg1. The good secondary combustion in the MMH reduced the particle organic matter(POM) and gaseous emissions, but not substantially the elemental carbon (EC, i.e. soot)emission, and the typical PM1 values were 0.7–0.8 g kg1.
The particle number emissions were high, varying from 1.0 × 1014 kg1 to 42 × 1014 kg1
and did not correspond with the completition of combustion. The particle numberdistributions were mainly dominated by ultrafine (<100 nm) particles, but varied dependenton combustion conditions. The electronmicroscopy analyses showed that ultrafine particleswere composed mainly of K, S and Zn. From the smouldering combustion, particles werecomposed mainly of carbon compounds and they had a closed sinteredlike structure, due toorganic matter on the particles.
Controlling the gasification rate via the primary air supply, log and batch size, as wellas fuel moisture content, is important for the reduction of emissions in batch combustionappliances. To reduce emissions of sauna stoves, the combustion technique or secondaryremoval techniques must be developed.
Universal Decimal Classification: 504.5, 544.452, 551.510.42, 628.532, 662.613.13,662.613.5, 662.63, 683.943, 697.243.5National Library of Medicine Classification: WA 754CAB Thesaurus: combustion; burning; heaters; stoves; wood; fuelwood; pellets; oats;rapeseed; bark; peat; wood smoke; wood ash; air pollutants; gases; dilution; emission;particles; distribution; particle size distribution; aerosols; measurement; determination;characterization; morphology; analysis; chemical analysis, chemical composition; carbonmonoxide; organic matter; organic compounds; electron microscopy
AcknowledgementsThis study was carried out in the Fine Particle and Aerosol Technology Laboratory in the
Department of Environmental Science during the years 2002–2008. I thank the Head of
Department, Professor Jukka Juutilainen, for the opportunity to work in his Department. This
research was financially supported by the Finnish Funding Agency for Technology and
Innovation (TEKES), the Ministry of the Environment, the Ministry of Agriculture and Forestry,
and several manufacturers.
I wish to express my gratitude to my supervisor, Professor Jorma Jokiniemi, for supervising
and guiding my thesis, and providing a research environment for this thesis. I am also thankful
to Jorma Joutsensaari PhD and Pertti Pasanen PhD for their encouragement and supervision of
this work. I am grateful to the official reviewers of the thesis, Christoffer Boman PhD from the
University of Umeå, Sweden, and Joakim Pagels PhD from the University of Lund, Sweden, for
reviewing and making valuable comments on the thesis. I am grateful to Vivian Paganuzzi for
the expert revision of the language.
I also thank my coauthors, Olli Sippula MSc and Kati Hytönen MSc from the University of
Kuopio, Jussi Lyyränen PhD, and Unto Tapper PhD, of VTT, the Technical Research Centre of
Finland, and all other colleagues at the Finnish Meteorological Institute, the National Public
Health Institute, and the TTS Research, for their wonderful cooperation during the work. I wish
to thank all my colleagues in the Fine Particle and Aerosol Technology Laboratory. In addition,
special thanks go to Pentti Willman for his assistance in laboratory analyses, and to Anita
Kajander for her help.
Finally, I warmly thank my parents, Hilkka and Matti, for their loving support and
encouragement throughout my life. Kiitos äiti ja isä! The greatest and warmest thanks go to my
wife Maria for love, care and understanding, and to our wonderful children Emilia, Mikael,
Olivia, Adalmiina and Eemil: you all bring a lot of happy moments to our life.
Kuopio, August 2008
Jarkko Tissari
List of acronyms and definitionsCMH Conventional masonry heater. Masonry heater with traditional
rift grate.
Coarse fly ash Coarse (> 1 µm) low volatile ash compounds that are ejected
from the fuel bed into flue gas.
DLPI Dekati low pressure impactor
DR Dilution ratio
DT Dilution tunnel
EC Elemental carbon
ED Ejector diluter
ELPI Electrical low pressure impactor
Fine ash Volatile ash compounds (below size of 1 µm, primarily
alkali metal compounds) that are volatilized during combustion.
FMPS Fast mobility particle sizer
GMD Geometric mean diameter
MH Masonry heater. Heavy (>800 kg) wood combustion
appliance which stores energy released from combustion to the
massive structure of heater and slowly radiates into indoor air.
MMH Modern masonry heater. Masonry heater with unique grate
design.
MMD Mass mean diameter
NC Normal combustion. The case where the CMH was used with
the best available operational practice for the heater.
OGC Organic gaseous compounds measured with flame ionization
detector (FID).
OC Organic carbon
PM Particle mass or particulate matter
PMx Particle mass below aerodynamic size of x µm.
POM Particle organic matter: determined by converting the mass of
the organic carbon (OC) to the total mass of the organic
compound (POM) using a factor that accounts for the
oxygen, hydrogen, and some other elements present. The scale
factor of 1.8 was used in this thesis.
PRD Porous tube diluter
RWC Residential wood combustion
Soot Complex mixture consisting mainly of amorphous elemental
carbon (EC) and organic material. Typically the blacker the
smoke is, the higher is the elemental carbon content.
S or WS Stove. Light wood combustion appliances that is freestanding,
not storing or semistoring wood heaters usually made of steel.
SC Smouldering combustion. Generally, highly incomplete
combustion caused by overall lack of oxygen.
SEM Scanning electron microscopy
SS Sauna stove. Heaters used for heating sauna rooms. They are
typically made of steel and have no means of preserving the
heat produced.
TEM Transmission electron microscopy
List of publications
This thesis is based on four original publications referred to the text by their Roman
numerals (I–IV).
Paper I: Tissari, J., Hytönen, K., Sippula, O., Jokiniemi, J. (2008) The effects of
operating conditions on emissions from masonry heaters and sauna
stoves. Accepted to Biomass & Bioenergy.
Paper II: Tissari, J., Lyyränen, J., Hytönen, K., Sippula, O., Tapper, U., Frey, A.,
Saarnio, K., Pennanen, A., Hillamo, R., Salonen, R., Hirvonen, M.R.,
Jokiniemi, J. (2008) Fine particle and gaseous emissions from normal
and smouldering wood combustion fired in a conventional masonry
heater. Accepted to Atmospheric Environment.
Paper III: Tissari, J., Hytönen, K., Lyyränen, J., Jokiniemi, J. (2007) A novel field
measurement method for determining fine particle and gas emissions
from residential wood combustion. Atmospheric Environment 41, 8330–
8344.
Paper IV: Tissari, J., Sippula, O., Kouki, J., Vuorio, K., Jokiniemi, J. (2008) Fine
particle and gas emissions from the combustion of agricultural fuels fired
in a 20 kW burner. Energy & Fuels 22, 2033–2042.
The original articles have been reproduced with permission of the copyright holders.
Author's contribution
The research reported in this thesis was mainly carried out at the Fine Particle and Aerosol
Technology Laboratory of the University of Kuopio, Finland, during 2002–2008. Paper I is
based on the experimental work to investigate the emissions from masonry heaters and sauna
stoves. The experiments were constructed mainly by the author and carried out with the help
of K. Hytönen MSc and O. Sippula MSc (Tech.) under the supervision of Prof. T. Raunemaa
and Prof. J. Jokiniemi. The data analysis and interpretation were performed by the author.
Papers II–IV were carried out under the supervision of Prof. J. Jokiniemi. Paper II
characterised the fine particle emissions from a conventional masonry heater during
smouldering and normal combustion conditions. The experiments described in Paper II were
carried out by the author with the help of K. Hytönen MSc, J. Lyyränen PhD, A. Pennanen
PhD and A. Frey MSc. In Paper II the scanning electron microscopy samples were collected
by J. Lyyränen PhD and analysis was performed by U. Tapper PhD. The data analysis and
interpretation were mainly performed by the author with the help of O. Sippula MSc (Tech.).
The field experiments from residential appliances described in Paper III were carried out by
the author with the help of K. Hytönen MSc, J. Lyyränen PhD and T. Turrek MSc. The data
analysis and interpretation were mainly performed by the author. The PAH sampling and
analysis were carried out by K. Hytönen MSc.
The wood pellet and agricultural fuel combustion experiments described in Paper IV were
carried out at the TTS Research, Rajamäki, Finland. The combustion experiments were
mainly arranged by J. Kouki and K. Vuorio. The emission measurements were carried out by
the author and O. Sippula MSc (Tech.). The data analysis and calculation of results were
carried out by the author. The interpretation of data was performed by the author with the help
of O. Sippula MSc (Tech.).
The author was responsible for writing in all of the Papers.
CONTENTS
1 INTRODUCTION..................................................................................17
2 RESIDENTIAL WOOD COMBUSTION.............................................192.1 Composition of wood fuel ..............................................................................................192.2 Wood combustion process ..............................................................................................19
2.2.1 Drying and pyrolysis .............................................................................................192.2.2 Combustion ..........................................................................................................202.2.3 Batch and continuous combustion..........................................................................20
2.3 Requirements for complete combustion ..........................................................................202.3.1 Combustion temperature .......................................................................................202.3.2 Combustion air supply ..........................................................................................212.3.3 Mixing of combustion air and fuel gas...................................................................212.3.4 Operational parameters..........................................................................................22
2.4 Residential combustion appliances..................................................................................222.4.1 Masonry heaters....................................................................................................222.4.2 Wood stoves .........................................................................................................232.4.3 Wood log boilers...................................................................................................232.4.4 Pellet burners and boilers ......................................................................................242.4.5 Stoker burners.......................................................................................................24
3 FORMATION OF EMISSIONS............................................................253.1 Formation of gaseous emissions and organic particles.....................................................253.2 Formation of soot particles .............................................................................................263.3 Formation of ash particles ..............................................................................................27
4 AIMS OF THIS STUDY ........................................................................29
5 MEASUREMENT METHODS .............................................................315.1 Combustion arrangements, particle sampling and dilution ...............................................315.2 Particle number and number size distribution measurements ...........................................325.3 Particle mass and mass size distribution measurements ...................................................335.4 Analysis of particle chemical composition ......................................................................335.5 Analysis of particle morphology.....................................................................................345.6 Gas measurements..........................................................................................................34
6 RESULTS AND DISCUSSION ............................................................. 376.1 Fine particle and gas emissions from RWC .................................................................... 37
6.1.1 Particle number emissions and number size distributions........................................376.1.2 PM1 emissions and particle mass size distributions.................................................416.1.3 Particle composition ..............................................................................................426.1.4 Particle morphology ..............................................................................................466.1.5 Gas emission .........................................................................................................47
6.2 Effect of operational practices on emissions................................................................... 476.2.1 Effect of operation in continuous combustion.........................................................476.2.2 Effect of fuel loading on emissions in batch combustion ........................................486.2.3 Emissions in smouldering combustion ...................................................................49
6.3 Effect of sampling and dilution on fine particle emissions .............................................. 496.3.1 Particle losses........................................................................................................496.3.2 Transformation of particles....................................................................................50
6.4 Cases of high and low fine particle emissions from RWC appliances and suggestions for ... emission reduction measures ................................................................................ 51
7 SUMMARY AND CONCLUSIONS ..................................................... 55
8 REFERENCES ...................................................................................... 57
APPENDIX I: EMISSION FACTOR TABLESAPPENDIX II: CALCULATION OF DR AND EMISSION FACTORSAPPENDIX III: PAPERS
Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:163 (2008) 17
1 Introduction
Fine particles (PM2.5: Particle Mass belowaerodynamic size of 2.5 µm) are one of the mostimportant pollutant in outdoor air (Pope andDockery, 2006). The impact of airborne particleson health is very varied, ranging from causingmild, shortlived symptoms to contributing to theonset or worsening of chronic conditions andpremature death (Dockery et al., 1993; Kappos etal., 2004; Salonen and Pennanen, 2007). A safethreshold level for fine particle concentrations inurban air cannot yet be determined (WHO, 1994).
Residential wood combustion (RWC) forheat production has been assessed to be a majorsource of fine particle mass emissions, particulatepolyaromatic hydrocarbons (PAHs) and certaingaseous pollutants such as volatile organiccompounds (VOCs) throughout Europe (e.g.Olsson et al., 1997; Christensen et al., 1998;Salonen and Pennanen, 2007). In Finland, themain source of fine particles is longrangetransport, whereas traffic, energy plants,industrial processes and residential woodcombustion (RWC) are the most importantstationary emission sources. A recent studyreported that RWC accounted for 25% of thestationary combustion emissions in Finland in2000, based on primary PM2.5 (Karvosenoja etal., 2008). On the other hand, it has beenestimated that RWC can produce locally as muchas 20–90% of the wintertime fine particleemissions (Muhlbaler Dasch, 1982; Boman et al.,2003).
According to the latest studies, the healtheffects of inhaled aerosol particles from woodcombustion may be more harmful than haspreviously been thought (Boman et al., 2003;Naeher et al., 2007). Health studies in residentialareas with prevalent smallscale woodcombustion have indicated that asthmaticsubjects are vulnerable to this kind of airpollution (Larson and Koenig 1994; Boman et al.2003). In many developing countries, woodcombustion is a major source of energy forindoor cooking and heating, and epidemiologicalstudies have reported, a high incidence of lungcancer among women who use stoves in China
(Liu et al., 1993; Pintos et al., 1998). The smallsize of the particles may increase significantly thepopulation's exposure to respiratory ailments andother health risks (Seaton et al., 1995; Pope et al.,2002).
On the other hand, it is well known thatatmospheric aerosols influence climate (IPCC,2007). Flaming combustion at high temperaturesproduces "sooty" smoke which strongly absorbssolar radiation and warms the atmosphere(Colbeck et al., 1997). However, fine particlesprimarily cool the atmosphere, becausesmouldering combustion at low combustiontemperatures produces an aerosol thatpredominantly scatters sunlight, and the fineparticles form clouds that reflect sunlight back tospace (e.g. Colbeck et al., 1997). Furthermore,incomplete wood combustion produces methaneand nitrogenrich fuels N2O that are the effectivegreenhouse gases (Seinfeld and Pandis, 1998).However, because biomass fuels are carbondioxide (CO2) neutral, according to differentinternational requirements, the use of theserenewable energy sources will be increased in thenear future, in order to decrease the emissions ofgreenhouse gases. According to an EUagreement, the use of renewable energy inFinland has to increase from 28% to 38% by2020. This also requires an increase in all kindsof wood energy.
The combustion conditions are verydifferent in smallscale combustion appliancesthan in large power plants. In small combustionunits, the local atmosphere and temperature varyconsiderably depending on the grate and burner.In addition, there are many different uncontrolledfactors that also affect the combustion conditions.For example, numerous types and models ofwood combustion appliances in use, and woodfuel can originate from several tree species. Theoperational practices of RWC also vary widely(e.g., fuel seasoning, combustion patterns,combustion rates, kindling approaches etc.) andoften these practises are not well established fromthe emission point of view. Thus, the emissionsfrom RWC have been demonstrated to be highly
Jarkko Tissari: Fine particle emissions from residential wood combustion
18 Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008)
variable (Nussbaumer, 2003; Johansson et al.,2003; Johansson et al., 2004; Sippula et al.,2007a).
In most cases, small wood combustionappliances are not equipped with a flue gasfiltering system. Because they also have a highprobability of incomplete combustion, whichleads to the production of fine particles andhazardous organic compounds, RWC cause airquality problems locally in densely populatedareas where wood combustion is common(Glasius et al., 2006). The dispersion and thedilution of the particles are dependent on theprevailling weather conditions (Boman et al.,2003b). Most problems occur during winterperiods with stagnant weather conditions, andwood combustion can result in local particlelevels comparable to heavily trafficked streets(Glasius et al., 2006). Because of varyingoutdoor temperatures, the use of woodcombustion appliances is seasonal and air qualityproblems occur in episodes (e.g. Kukkonen et al.,2005). Emission height in RWC is usually only afew meters above the ground. Thereforeemissions do not have much time to dilute,oxidize or react chemically before people wholive in the neighbourhood of wood combustionare exposed.
Primarily due to their health effects, thereis a need to decrease the particle and gaseousemissions from wood combustion in small scaleappliances. Because the mechanisms of the healtheffects are not yet known exactly, studying bothfine particle physical and chemical properties isimportant (Lightly et al., 2000). These properties(e.g. particle size and morphology, number andmass concentration, chemical composition) aredependent on combustion conditions. In future,there will be more stringent emission regulationswhich will also consider emissions fromresidential combustion. In many cases, flue gasfiltering systems are still not economically
feasible in small scale appliances, and on theother hand there is a large potential to decreaseemissions by developing the combustiontechnology itself. Thus, there is actual need to getdetailed information from the particle and gasemissions in small scale appliances. This enablesthe development of low emission combustiontechniques and increases understanding on therelation between certain health and climateeffects to put right measures to reduce harmfuleffects of from RWC.
Generally, there are several studies onemissions from woodfired appliances (e.g.Hedberg et al., 2002; Johansson et al., 2004;Koyuncu and Pinar, 2007). However, there islack in the present knowledge, especiallyconcerning fine particle emissions and theircomposition during different combustionconditions. Moreover, there are not any studiesfrom emissions in the Finnish context. Inaddition, due to the difference in climateconditions and construction, the combustionappliances and operational practices are differentin Finland than in many other countries and thus,the present knowledge can not be directlygeneralized to the Finnish context.
In this thesis, a general picture on thesignificance of different factors influencing thefine particle emissions from RWC applianceswas obtained. This thesis was focused on thechemical and physical composition of fineparticle and gas emissions during differentcombustion conditions from real RWCappliances used in Finland, excluding theemissions of single organic compounds such asPAH and VOC. The investigation was based onlaboratory and field experiments applyingextensive and unique particle sampling methods.The literature review part of this thesis isconcentrated on the formation of emissions inRWC and the combustion conditions in smallscale appliances.
Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008) 19
2 Residential wood combustion
2.1 Composition of wood fuel
Fuel properties have an important effect onthe combustion of solid fuel. In contrast to manyother fuels, the volatile matter content of wood ishigh, typically 80% by dry weight, and thatstrongly affects the combustion. Wood fuel iscomposed primarily of carbon (C), oxygen (O)and hydrogen (H). The carbon content of drywood is typically 47–52%, whereas the oxygenand hydrogen contents are 38–45% and 6.1–6.3%, respectively (Van Loo and Koppejan,2008).
Structurally, wood is composed mainly ofcellulose (40–45% of dry weight), hemicellulose(20–35%), lignin (15–30%), and to a lesser extentof extracts. The fibre walls of wood consistmainly of cellulose (C6H10O5), which is acondensed polymer of glucose. Hemicelluloseconsists of various sugars such as glucose, whichencases the cellulose fibers. Lignin (e.g.C40H44O14) is a high molecular mass complexnonsugar polymer that gives strength to thewood fibre (Van Loo and Koppejan, 2008).
Wood fuel also contains other inorganiccompounds that are bounded to the organicstructure of wood. Nitrogen content is low,typically below 0.5%. Mineral content istypically below 0.5%. The main compounds arecalcium (Ca), potassium (K), magnesium (Mg),manganese (Mn), sulphur (S), chlorine (Cl),phosphorus (P), iron (Fe), aluminium (Al) andzinc (Zn) (e.g. Paper IV, Table 1).
In addition, wood fuel always containswater. The water content of a dry wood pellet isabout 6%, whereas the water content of woodlogs is 10–30%, and that of wood chips is evenhigher, up to 60%.
2.2 Wood combustion process
Combustion is a reaction where fuel reactswith oxygen, and this chemical process produceheat energy. The combustion of fuel particle iscomposed of several combustion phases, e.g.
drying and heating of fuel, pyrolysis, firing andcombustion. The first phases need heat, whereasflaming combustion and combustion of residualchar produces heat. In the combustion of woodfuels, the combustion reactions take placeprimarily between gaseous products but thecombustion of residual char is composedparticularly of reactions between gases andcarbon in the surface of solid char.
2.2.1 Drying and pyrolysis
In the first phase, the fuel particle warm upto drying temperature, after which most of thewater is vaporized. The drying of porous fuelparticle is dependent on the fuel water content,the rate of heat transport and vapour pressuresbetween fuel and the surrounding (Rogge et al.,1998; Simoneit et al., 1999; Van Loo andKoppejan, 2008).
Fuel temperature increases and the volatilehydrocarbons begin to vaporize when the surfaceof the fuel has dried enough. Pyrolysis iscomposed of several complex parallel andsequential chemical reactions. In pyrolysis, thefuel constituents start to hydrolyze, oxidize anddehydrate, and the large structures (e.g. cellulose,hemicellulose and lignin) degrade. Duringpyrolysis, many different gaseous and liquidproducts such as volatile organic compounds,water, CO2, H2 and carbon monoxide (CO) areformed (e.g. Rogge et al., 1998; Simoneit et al.,1999; Van Loo and Koppejan, 2008).
It has been observed that thedevolatilization of wood starts, anddevolatilization rate substantially increases,above the temperature of 200 °C (Van Loo andKoppejan, 2008). The decomposition ofhemicellulose occurs at 200–350 °C, sincecellulose decomposes at 250–450 °C. At 400 °C,most volatiles are gone and the devolatilizationrate decreases rapidly. The lignin decomposesthroughout the temperature range from 200 to500 °C, but the main weight loss occurs at highertemperatures.
Jarkko Tissari: Fine particle emissions from residential wood combustion
20 Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008)
2.2.2 Combustion
The combustion gases kindle when theproduction of heat is higher than the heat lossesto the environment. Typically, the products ofpyrolysis burn as a diffusion flame round the fuelparticle and produces heat also for the otherpyrolysis reactions. The pyrolysis gases areoxidized in the interface of air and pyrolysisproducts. Because of the increased heat rate, thetemperature of the fuel increases, and combustionaccelerates until the production of pyrolysis gasesslows down. During pyrolysis, the ratio of C/H infuel increases, and the combustion of residualchar starts; this is best described as the gradualoxidation of the reactive char (solid phasecombustion) (e.g. Rogge et al., 1998; Simoneit etal., 1999).
Although the residual char content frombiomass combustion is typically only 10–30% bydry weight, the energy produced is 25–50% ofthe total energy produced during combustion.The combustion of residual char is composed ofboth reactions between gaseous products andparticularly reactions between gases and thesurface of solid char. The diffusion rate ofoxygen to the surface of char is very slow. Thisrestricts the combustion rate of residual char, sothe combustion of char is the slowest phase.Typically for example in the wood logcombustion, char combustion begin alreadyduring pyrolysis. In addition, the combustionreactions occur also inside the residual char, andthus the porosity of char strongly affects thecombustion time. (e.g. Flagan and Seinfeld,1988; Van Loo and Koppejan, 2008).
2.2.3 Batch and continuous combustion
In RWC appliances, the combustionprocess can be a continuous or batch typeprocess. With continuous fuel feeding, differentcombustion phases occur in the fuel layer, andcombustion is steady, and can be bettercontrolled than in batch combustion appliances.However, the combustion process can be unstableespecially in the interference, cleaning, onoffusing and low load combustion phases incontinuous combustion appliances. In batch
burning appliances, there is a distinct separationbetween combustion phases in position and time(Van Loo and Koppejan, 2008). The combustioncan be divided into three phases: (1) the firingphase; (2) the combustion phase; and (3) the burnout phase. Based on experience on combustionconditions during batch combustion, in thisstudy, the combustion phases are defined asfollows: The firing phase is defined as lastingfrom the ignition of the fire until the momentwhen the minimum oxygen concentration isreached (Paper I, Figure 2). This phase includesdrying, warming and the initial part of thepyrolysis of the fuel batch. The combustion phaseincludes the strong and dying flamingcombustion. The combustion phase is the periodfrom the minimum oxygen concentration up to aconcentration of 14%, and the burn out phase isfrom then on. In the next batch, all thecombustion phases occur again sequentially.
2.3 Requirements for complete combustion
The most important parameters forcomplete combustion conditions are (1) a highcombustion temperature, (2) a sufficient amountof combustion air supply, and (3) adequatemixing of combustion air and fuel gas (e.g.Nussbaumer, 2003; Van Loo and Koppejan,2008).
2.3.1 Combustion temperature
The combustion temperature affectsprimarily the burn out of combustion compounds.The oxidation reactions are faster and morecomplete, and the combustion time shorter inhigh temperatures than at low ones. In RWCappliances, the heat can be transferred byconduction, convection or radiation. The heatcapacity and density, thickness, insulation andsurface properties of the material used in thefirebox affect the combustion temperature. Forexample, the radiation loss through the glass doorwill be large per unit surface area, compared withthe conductive heat loss through the combustionchamber walls per unit surface area (Van Looand Koppejan, 2008). For complete combustion,it is necessary to minimize heat losses from the
2. RESIDENTIAL WOOD COMBUSTION
Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008) 21
combustion chamber. In light stoves, a highercombustion chamber temperature can beachieved by improving the insulation of thecombustion chamber. The capability of heatstorage (ceramic or soapstone material) inmasonry heaters and brickwork in boilers enablehigher combustion temperatures. In masonryheaters, the hot closed firebox surface reflectsheat back into the flame and creates the gasturbulence needed for complete combustion. Inopen fireplaces, cookstoves or campfires, due tothe lack of radiative heating, much heat is oftenlost to the surroundings and this restricts thecombustion temperature and combustion rate(e.g. Van Loo and Koppejan, 2008).
In RWC appliances, there is normally anoverall excess of oxygen to ensure a sufficientmixing of combustion air and fuel gas. However,the combustion temperature decreases as afunction of the excess air ratio due mainly to theheating of inert nitrogen in the air. Thetemperature of the combustion chamber can beconsiderably increased by preheating the air. Inaddition, the vaporization of the fuel moistureuses energy released from the combustionprocess; it lowers the temperature in thecombustion chamber, which slows down thecombustion process (e.g. Van Loo and Koppejan,2008).
2.3.2 Combustion air supply
A sufficient air supply is also veryimportant for complete combustion (e.g. Van Looand Koppejan, 2008). Although, a combustionprocess may have globally an excess of air, inmany cases there may be locally deficiency of airdue to poor mixing. An overall lack of oxygenleads the smouldering combustion conditions.
The gasification rate of wood is controlledmainly by the primary air supply, but the log andbatch sizes (i.e. total area of wood logs) alsostrongly affect the gasification rate of wood inbatch combustion. Thus, a restriction of the airsupply and too large fuel batches in relation tothe size of the air intakes, which are commonoperational errors in logwood heating, cause aninsufficiency of the air supply.
The addition of air in RWC appliances canbe carried out by a forced or natural draught. Thedraught affects air flow rates to the combustionappliances and also the combustion conditions. Innatural draught appliances, the chimney damperis used to control the flow conditions in thefirebox, but too low and too high flow rates occurin practise. A too low draught leads toinsufficient air and the dying of the fire. A toohigh draught leads to a lower combustiontemperature due to the high excess air, or anincrease in the gasification rate and aninsufficiency of air, depending on the fuel surfacearea loaded in the firebox. In continuouscombustion appliances, flue gas fans or airblowers are used to control the combustionprocess and draught conditions.
2.3.3 Mixing of combustion air and fuel gas
Complete combustion requires goodmixing of secondary air and combustion gases,and a satisfactory residence time for the fluegases for oxidation (e.g. Stehler, 2000;Nussbaumer, 2003). Good mixing reduces theamount of air needed, providing a local andoverall excess air ratio and higher combustiontemperature. Inadequate mixing in thecombustion chamber leads to local fuelrichcombustion zones and increases emissions.
Due to the high volatile matter content inwood fuel, complete secondary combustion isalso important in wood combustion. In moderncombustion appliances, the combustion air issupplied evenly in three stages to the firebox orburners. The primary air regulates thecombustion rate, whereas the secondary andprobable tertiary air enhances secondarycombustion. Introduction of the heated secondaryair into the top of the primary combustionchamber enhances the ignition of the combustiongases in the secondary combustion chamber. Inmodern boilers, O2 or a CH (hydrocarbons)sensor are more and more often used to ensuregood combustion conditions and a sufficient airsupply (e.g. Stehler, 2000).
Particularly in the char combustion phase,the radical concentrations may be too low forcomplete combustion. Without radicals, the
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22 Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008)
combustion happens by the diffusion of oxygento the surface of char, which is slow andincreases CO emissions (e.g. Flagan andSeinfeld, 1988; Van Loo and Koppejan, 2008).
2.3.4 Operational parameters
In addition, many uncontrolled factorsaffect combustion conditions and emissions(Nussbaumer, 2003; Johansson et al., 2003;Johansson et al., 2004). The combustion of woodfuel is dependent on its chemical (heating value,reactivity), physical (heat capacity, heatconductivity) and structural (particle size,density, porosity) properties. For example, fueldensity influences the combustion chambervolume to energy input ratio, and also thecombustion characteristics and thermal behaviourof the fuel. Operational practices, e.g., fuelseasoning, the distribution of fuel inside thecombustion chamber, combustion patterns,combustion rates, and kindling approaches, alsoaffect emissions.
2.4 Residential combustion appliances
In many developing countries, biomasscombustion in small appliances is a major sourceof energy for indoor cooking and heating (e.g.Viau et al., 2000). For example, in India hundredof millions of households use biofuels forcooking energy (Venkataraman and UmaMaheswara Rao, 2001). On the other hand,biomass fuels are combusted in gratefiredboilers or cofired in pulverized coal combustionfrom a few megawatts up to 1000 MW. Inaddition, large amounts of biomass burnuncontrolled, for example in natural fires(Robinson et al., 2007; Jalava et al., 2006). InFinland, wood is used mainly as an auxiliary heatsource in onefamily houses, and is combusted inmasonry heaters and different types of stoves.Different forms of wood fuels are used, such aswood logs, densified logs and pellets, and woodchips.
The common types of RWC devices havebeen described by, for instance, Baxter et al.(2002) and Van Loo and Koppejan (2008). The
most common RWC appliances can be dividedinto five categories: three types of batchcombustion appliances: (1) masonry heaters, (2)wood stoves and (3) wood log boilers; and twotypes of continuous combustion appliances: (4)pellet burners and boilers, and (5) stoker burners.
2.4.1 Masonry heaters
Masonry heaters (Paper I, Figure 1a,b;Paper III, Figure 1) have a very high mass,typically from about 800 to 3000 kg, and can beup to 6000 kg. They are enclosed combustionappliances made of masonry products, acombination of masonry products and ceramicmaterials, or soapstone (Stehler, 2000). Othersare covered with decorative tiles and weredeveloped in the 1700s as the first efficient woodfiring device in Sweden (Van Loo and Koppejan,2008). In these heaters wood is combusted in arelatively short period of time and at high power,which means that the combustion rate andtemperature are high. Typically, the heaters havean upright firebox with a glass door. In thecontraflow (e.g. Paper II, Figure 2) system, theexhaust gas flows from the firebox to an uppercombustion chamber, and goes down through theducts into the chimney from the bottom or top ofthe heater. The energy released (40 to 100 kWh)is efficiently stored (combustion efficiencytypically 75–85%) in the large mass surroundingthe firebox and the ducts. Masonry heatersproduce both primary and supplemental heat,when the heat stored in the stone mass slowlyradiates (at an average rate of 1–3 kW) into theindoor air for the next 1 to 2 days, so they arewell suited for Nordic coldclimate conditions.Most of the heaters have a conventional (rift)grate, and are called conventional masonryheaters (CMH). In a Finnish modern masonryheater (MMH), in contrast to a CMH, the primaryairflow is controlled and secondary air is directedto envelop the fuel batch (e.g. Paper I, Figure1b). Baking ovens (Paper III, Figure 1), whichare common in Finland, have a flat grate withoutrifts, and the combustion air is introducedthrough the oven door. There are also severalcombinations of baking ovens and MHs.
2. RESIDENTIAL WOOD COMBUSTION
Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008) 23
2.4.2 Wood stoves
Wood stoves (WS or S) are freestanding(mass <800 kg), enclosed, notstoring or semistoring wood heaters usually made of steel,sometimes covered with ceramic materials orsoapstone to increase heat storage. In Finland,they are used primarily for aesthetic effects andsecondarily as supplementary heating sources inhouses, and as the primary source of heat insummer cottages. In warmer countries they areused both as the primary source of residentialheat and for supplementary heating. Stovesrelease heat by radiation and convection to theirsurroundings. Wood stoves control combustionor burn time by restricting the amount of air thatcan lead the smouldering combustion conditions.In modern appliances, secondary air is preheatedand introduced outside the primary combustionzone, in order to get good secondary combustion.In many appliances, the combustion chamber issmall and some are surrounded by ducts throughwhich floor level air is drawn by naturalconvection, heated, and returned to the room (e.g.Van Loo and Koppejan, 2008).
In the USA, catalytic stoves are also used.These are equipped with a ceramic or metalhoneycomb device, called a combustor orconverter, which is coated with a noble metalsuch as platinum or palladium. The catalyticcombustor is usually placed in the flue gaschannel beyond the combustion chamber. Thecatalyst material reduces the ignition temperatureof the unburned VOC and CO in the exhaustgases, thus augmenting their ignition andcombustion at normal stove operatingtemperatures (EPA, 1996a; Van Loo andKoppejan, 2008).
In Finland, sauna rooms are heated bysauna stoves (SS: Paper I, Figure 1c; Paper III,Figure 1), which are made of steel and have nomeans of reserving the heat produced. Thecombustion technique is very simple. Only abouthalf of the released energy can be stored in thestones on the stove and consequently the exhaustgas temperature is high. The momentary need ofheating in the sauna room is very high, so SS arealso operated at high power in a similar way tomasonry heaters.
Open fire heaters (open fireplaces)typically have large fixed openings in front of thefire bed and dampers above the combustion areain the chimney to limit room air and heat losseswhen the fireplace is not being used. They havevery low thermal efficiency; in worst cases theyconsume more energy than they produce. Insertsare nowadays used to update an existing fireplaceto a cleanerburning and more efficient heatsource (EPA, 1996b; Houck and Tiegs, 1998;Van Loo and Koppejan, 2008).
Cookstoves are very common appliancesused as a source of energy for indoor cooking andheating in many developing countries. They arevery simple appliances, usually simple tripods orthreestone stoves, or portable metal or ceramiccookstoves with efficiency from 8 to 30 % (Oahnet al., 1999).
2.4.3 Wood log boilers
Central boiler systems deliver heat into theradiator grid of a dwelling. In Finland, underfloorheating is the most common in new detachedhouses. Heat circulation pumps distribute the hotwater to the radiators, and thermostats regulatethe heating power in the rooms to be heated. Theboilers, which are made of steel, can be dividedinto three categories according to airflow designsin combustion, such as updraught (also known asoverfire), downdraught (underfire) andcrossdraught boilers (Johansson et al., 2004). Thetraditional updraught wood log boilers operate ina similar way as wood stoves and masonryheaters. The heat released in combustion isrecovered with a heat exchanger and stored in thewater space in the boiler. The most problematicare multifuel boilers, which can burn wood, oil,or pellets, but are primarily used for wood logcombustion with an upgraught technique.Because of the small firebox and water space inthe boiler, the use of multifuel boiler without aheat storage tank can lead to smoulderingcombustion conditions. Modern wood boilers areusually designed for downdraught orcrossdraught combustion. Often they have asecondary combustion chamber, which isnormally insulated with ceramics, and connectedto storage tanks. In crossdraught boilers, because
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the flue gas flow resistance is quite high, a fluegas fan is needed. Advanced control devices suchas O2 sensors, air control and staged aircombustion are also used (Baxter et al., 2002;Johansson et al., 2004; Van Loo and Koppejan,2008).
2.4.4 Pellet burners and boilers
Pellet burners can be installed separatelyin watercooled multifuel boilers or updraughtboilers, or integrated with boilers (Baxter et al.,2002; Johansson et al., 2004). Modern applianceshave heat control in large power scale with O2sensors, movable grates, effective heat exhangersand large ashboxes (Stehler, 2000). The feedingof pellets from the fuel tank to the burner istypically controlled by a fully automatic systemconnected to the burner automatics. In the burner,dispensing of pellets is typically done first with aseparate feeding screw through the airtight rotaryfeeder and thereafter by a burner screw in theburner head. This enables firesafe operation(Paper IV, Figure 2). The burners can beclassified into three types according to thefeeding principle: (1) topfeed burners (alsoknown as gravity or dropping feed or overfeed),(2) under feed (bottom fed) burners, and (3) sidefeed (or horizontally fed) burners. Respectively,
the burners can be classified also into four typesaccording to the combustion principle: grate,gasifier, bowl, and tube burner combustion.Normally, pellet boilers do not have heat storagetanks and the boiler is set at thermostat control,which results in a cyclic, intermittent operation ofthe pellet burner. Some burners operate with apilot flame, and others have electrical ignition,during low load combustion (Johansson et al.,2003).
Pellet stoves and pellet fireplace insertslook like wood stoves, but have active air flowsystems (recycling of indoor air) and a uniquegrate design (pellet burner) in the firebox. Theyare thermostatically controlled, and most havedifferent burn settings (Sippula et al., 2007a).
2.4.5 Stoker burners
Stoker burners operate in a similar way toside feed pellet burners, but they have largerburner screws and thus are suitable for wood chipcombustion. The flame burns horizontally in thesmall grate in the burner head. The burner ismounted partially inside the firebox of the boiler,and partially outside it. The fuel is fed accordingto the heat demand, and combustion air isintroduced from one or several blowers (Van Looand Koppejan, 2008).
Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008) 25
3 Formation of emissionsIn the complete combustion of
hydrocarbons only CO2 and H2O are produced. Inwood combustion, also unwanted combustionproducts are always produced, and so in additionto the main gas compounds N2, CO2, H2O and O2,flue gas also contains e.g. CO, H2, partiallycombusted hydrocarbons, sulphur dioxide (SO2),nitrogen oxides (NOx), hydrogen cloride (HCl)and different solid or liquid particles. The firstfine particles formed in wood combustion aresoot particles, which are already formed in theflame from hydrocarbons. The volatilization ofalkali metals from the fuel leads to the formationof fine fly ash particles and these also occur incomplete combustion (Oser et al., 2001; Bomanet al., 2004; Sippula et al., 2007a,b). In addition,aerosol from biomass combustion may includeliquid or tarlike parts, which are products fromthe gastoparticle conversion of organic vapoursin cooled flue gas. These heavy hydrocarbonsmay also condense onto existing particles(Pyykönen et al., 2007) or form new particles bynucleation (Shi and Harrison, 1999). In RWC, thecoarse particles are ejected mainly from bottomash and formed from low volatile ash compoundsand partially unburnt char (Flagan and Seinfeld,1988; Wiinikka, 2005).
3.1 Formation of gaseous emissions andorganic particles
In complete combustion, C, H and O infuel form only CO2 and H2O. Water vapourforms when water evaporates from fuel or duringhydrogen oxididation. CO2 is not considered tobe a greenhouse gas emission in biomasscombustion because forests and plants recyclecarbon dioxide when growing. Wood fuels alsocontain N, S and volatile mineral compounds.NOx compounds in flue gas are formed mainlyfrom fuel nitrogen. At high temperatures (over1400 °C), NOx is also formed from N2 incombustion air, but this is unlikely in RWC. N2Ois a very efficient greenhouse gas (Seinfeld andPandis, 1998), but N2O emissions from biomasscombustion are typically low (Van Loo and
Koppejan, 2008). In addition, NOx and volatileorganic compounds take part in the formation ofsecondary organic aerosol (SOA) in theatmosphere (Presto et al., 2005; Kleindienst etal., 2006; Robinson et al., 2007). Sulphur in fueloxidizes to SOx in combustion. SOx and NOxcompounds are also involved in the formation offine ash particles, and sulphur can form sulphuricacid (H2SO4). In addition, particularly from fuelwith high chlorine content, gaseous HCl mayform to a significant extent. In contrast toagricultural fuels, wood fuel contains only smallamounts of N, S and volatile alkali metals, andthus NOx, SO2 and HCl emissions are typicallylow (Van Loo and Koppejan, 2008).
The combustion of wood fuels in smallscale appliances is always partially incompletedue to local incomplete combustion conditionsaround the flame, low combustion temperatures,an insufficient air supply or poor mixing ofcombustion gases and air. As a result, CO andvolatile hydrocarbon emissions are formed. Inbatch combustion, when char combustion begins,the combustion chamber temperature decreases,which leads in most cases to a level below thatsufficient for the complete oxidation of CO. If thecombustion is highly incomplete, heavy complexorganic compounds are released to the flue gas.Poor combustion conditions can also beassociated with natural fires that are a largesource of organic matter in the atmosphere (e.g.Robinson et al., 2007).
Organic compounds can occur as bothgaseous and solid particles. They are typicallydivided according to their boiling points into veryvolatile (VVOC), volatile (VOC) andsemivolatile organic carbon (SVOC) comboundsand particle phase compounds (POM, particleorganic matter) (Tucker, 2001) or into thecorresponding functional group of molecularstructure (alkanes, alkenes, aromatics etc.).Incomplete biomass combustion produceshundreds of different organic compounds (e.g.Rogge et al., 1998; McDonald et al., 2000; Lee etal., 2005; Mazzoleni et al., 2007; Alfarra et al.,2007). One of the most important VOC from
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26 Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008)
biomass combustion is methane (CH4)(Johansson et al., 2004), which is also a verystrong greenhouse gas. The warming effect ofCH4 is 21fold that of CO2 (Seinfeld and Pandis,1998). Polycyclic aromatic hydrocarbons (PAH)are formed in the flame in local fuelrich areaswhen hydrocarbons polymerize instead ofoxidizing (Flagan and Seinfeld, 1988). In RWC,PAH compounds may also form from lightorganic compounds or from incompletecombustion of pyrolysis gases.
The particle formation mechanisms areshown in Figure 1. Aerosol from incompletewood combustion may contain liquid or tarlikeparts, which are products from the gastoparticleconversion of organic vapours in cooled flue gas,usually far below the temperature of 500 °C(Figure 1, line 4). Depending on environmentalconditions, organic compounds can be present inliquid or gaseous form. Heavy hydrocarbons maycondense onto existing particles (Pyykönen et al.,2007) or form new particles by nucleation (Shiand Harrison, 1999). If there are preexistingparticles in flue gas, it has been previouslyreported (Pyykönen et al., 2007) thathydrocarbons condense onto existing particlesrather than forming new particles by nucleation.The condensation of particles continues in thechimney and atmosphere when the combustionaerosol cools and is diluted. Evaporation andoxidation of organic aerosol is probable in theatmosphere (Robinson et al., 2007). Thus, theparticle properties of fresh RWC aerosol inwinter are different from those of aged aerosolespecially in summertime.
3.2 Formation of soot particles
Soot particles are formed mainly in theflame from hydrocarbons. The soot formationmechanisms are complex, and although there areseveral studies of the formation of soot particles,they are not yet well understood (e.g. Bockhorn,1994; D’Anna et al., 1994; Ishiguro et al., 1997;Kozi ski and Saade, 1998). Most soot particlesform in the fuelrich zone inside a diffusionflame and grow rather than oxidize to CO orCO2. Because of the insufficient mixing ofcombustion gases and air in RWC, the flame
zone always contains fuelrich areas even in thepresence of overall excess air during combustion.
In the first step of soot formation, PAHcompounds polymerize (Figure 1, line 1). In thenext step, the size of PAH compounds increasesand high PAH levels are reached. As a result,typically about 1–2 nm soot nuclei are producedby nucleation. After this, the nuclei increase bysurface reactions and coagulation, and form about10 nm core particles. More PAH compounds arebonded to the surface of core particles by surfacereactions and this leads to the formation ofprimary soot particles (e.g. Bockhorn, 1994;D’Anna et al., 1994; Ishiguro et al., 1997).
It has been observed that the primaryspherules are composed of lamellalikecrystallites (Ishiguro et al., 1997). The structureof these crystallites resembles that of graphite. Inthe outer shell of these spherules the crystallitestructure is directed according to the shape of thesurface, but in the spherules they are randomlyarrayed. The formation of the outer shell of sootspherules and the agglomeration of spherules areparallel and simultaneous. The surface of aspherule is composed of very stable elementalcarbon (EC) (Ishiguro et al., 1997).
The number concentration of carbonspherules in the flame is extremely high and thusthe formation rate of soot agglomerates is alsohigh. Most of the soot particles burn in theoxygenrich zone in the flame (Amann andSiegla, 1982; Wiinikka, 2005), but a minor partof the soot particles is released as agglomeratescomposed of about 30–50 nm solid carbonspherules (Figure 1, line 1). The extent of sootoxidation determines the size and number of thesoot particles released.
Both the combustion conditions and thequality of gaseous compounds influence sootformation (Bartok et al., 1991). The effect oftemperature/heat input and oxygen/local mixingconditions appear to be important within both thepreparticle chemistry, responsible for theformation of incipient soot particles, and the sootsurfacemass growth (Kozi ski and Saade, 1998).The oxygen content of dry wood is about 40%. Inthe pyrolyzation zone of the diffusion flame, theoxygen may increase the soot formation becauseit catalyses pyrolysis reactions more than do fuels
3. FORMATION OF EMISSIONS
Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008) 27
that contain no oxygen (Flagan and Seinfeld,1988).
3.3 Formation of ash particles
In good combustion conditions, fineparticle emissions are formed mainly by thevaporization of ashforming elements from thewood fuel (Sippula et al., 2007a,b; Figure 1, line2). The formation of fine ash particles begin byhomogenous nucleation, when the temperaturedecreases after the flame, and the vapour pressureof ash species also decreases (Jokiniemi et al.,1994; Boman et al., 2004). The vaporization isdependent on the chemical composition of thewood and the reactions of inorganic species(Olsson et al., 1997; Davidsson et al., 2002;Knudsen et al., 2004; Sippula et al., 2007a). Mostmineral compounds are bound to the organicstructure of biomass fuels and are easily releasedduring the pyrolysis of fuel. The combustiontemperature has an important influence onvaporization, so that greater amounts of ashparticles are released at high temperatures than atlow ones (Davidsson et al., 2002; Knudsen et al.,2004).
In wood fuels, potassium, sulphur,chlorine and sodium are very volatile. Further, inthe reducing area of flame, species that havelower vapour pressure such as zinc and calciummay also volatilize (Knudsen et al., 2004). Inwood combustion, the fine fly ash is composedmainly of potassium compounds such aspotassium sulphate (K2SO4), potassium chloride(KCl), potassium hydroxide (KOH) andpotassium carbonate (K2CO3) (Christensen et al.,1998; Valmari et al., 1998; Silva et al., 1999;Boman et al., 2004; Sippula et al., 2007a).
The release of alkali metals is influencedmainly by the fuel chlorine, sulphur and differentsorbent mineral concentrations. High chlorinecontent has been found to enhance the release of
alkali metals due to the formation of volatilealkali metal chlorides (Olsson et al., 1997;Knudsen et al., 2004). Knudsen et al. (2004)observed that the ratio of molar ratio of K/Si andCl/K is important for alkali emissions. If there aresilicates present, the aluminium and siliconcompounds can react with potassium, formingmore stable compounds (Jensen et al., 2000;Davidsson et al., 2002). Thus, a low K/Si ratiohas been observed to limit the release ofpotassium. A high Cl/K ratio increases therelease of alkali metals, since the chlorineprevents the potassium from combining withsilicates and instead favours high vapour pressurevolatile formation (Dayton et al., 1999; Knudsenet al., 2004). In contrast, a sufficient amount ofsulphur in the fuel may inhibit the effect ofchlorine throughout a sulfation reaction, in whichthe alkali metal chloride is converted to lessvolatile alkali metal sulphate (Sippula et al.,2008). Further, sulfation of other alkali metalspecies such as hydroxides may decrease therelease of alkali metals.
Very high fuel ash content in agriculturalbiomass, for example, may lead to operationalproblems such as fouling, slagging and corrosionof heat transfer surfaces in boilers, which reduceefficiency, and may even lead to costlyshutdowns and repairs (Dayton et al., 1995;Blander and Pelton, 1997; Davidsson et al., 2002;Lindström et al., 2007).
The coarse (~1–10 µm) particles occurringin biomass combustion are formed from lowvolatile ash compounds and partially are unburntchar (Figure 1, line 3). At low temperatures, largeash agglomerates are formed by agglomeration,but in sufficiently high temperatures ashcompounds may melt and form regular ashdroplets (Flagan and Seinfeld, 1988). Supercoarse particles (>10 µm) are formed fromresidual fly ash particles that are ejected from thefuel bed and carried upwards by the gas(Wiinikka, 2005).
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Release ofpyrolysis gases
Vaporization(K, Na, S, Cl, Zn...)
Char formation
Ejection ofcoarse fly ash andunburnt char particles
Coarse fly ash andunburnt char particles
Coarse particles (1–10 µm)
Super coarse particles (>10 µm)
Formation ofbottom ash(e.g. K Ca (SO )2 2 4 3
Charburn out
Sulphation andoxidation
Nucleation/condensation of alkalisulphates and zinc
Coagulation andcondensation
Condensation ofalkali chlorides
Condensation and/ornucleation oforganic vapours
Agglomeration andmelting of low volatile species(Ca, Fe, Si, Ti...)
CO
O2
CO22H O
C HX Y
Formation of lamellalike crystals
Formation ofsoot nuclei
Surfacegrowthandcoagulation
Formation ofcore particles
Formation of primarysoot particles
Agglomeration
Oxidation andburn out of sootparticles
Formation ofsoot agglomerates
Inception
PAH polymeration
12 nm
10 nm
3050 nm
501000 nm
Nucleation
PAH formation
(1)
(2)
(4)
(3)
Fine particles (<1 µm)Soot, POM and fine fly ash(K SO , K l etc.)2 4 C
Fuel
Figure 1. Illustration of the soot formation process (1), fine ash (2), coarse particles (3) and particleorganic matter (POM) (4) during residential wood combustion according to Wiinikka (2005), Ishiguro
et al. (1997) and Bockhorn (1994).
Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008) 29
4 Aims of this studyThe objective of this study was to assess
the role of different factors influencing fineparticle emissions from RWC. The main factorsstudied were fuel, combustion appliances,operational practices, and measurement methods.The investigation was based on laboratory andfield experiments applying extensive quantity andquality characterisation of gas and particlespecies and unique particle sampling methods.
The specific aims of the study were:
• To study the influence of combustionphase on emissions (Paper I).
• To characterise the fine particles inrelation to combustion appliance andcombustion conditions (Papers I–IV).
• To clarify how operational practicesaffect emissions from Finnishappliances (Papers I–III).
• To determine the effect of biomass fuelproperties on fine particle and gasemissions from a residential burner(Paper IV).
• To define emission factors for the mostcommon Finnish heaters, to compare theresults with those of other studies, andto provide uncertainty ranges of theemission factors used in emissioninventories (Papers I–IV).
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5 Measurement methodsThe measurement of fine particles from
RWC appliances is very challenging. The particlesize range is very large, and the flue gas containsparticles that vary from nanometers tomicrometers in size. In addition, fine particlesoccur in three states in the flue gas: soot,inorganic ash or organic species, which mayoccur in the gas phase prior to sampling andnucleates or condenses during sampling. Severalmeasurement devices have to be used if both thephysical and chemical properties of fine particlesare to be measured. Because of the variable andat least temporarily high vapour and particleconcentration and high temperature in the fluegas, the sample gas has to be diluted before it isled to the measurement devices. The optimaldilution ratio (DR) varies between differentdevices.
In this chapter, the combustionarrangements and the measurement techniques
and devices that were used are introduced. Themeasured appliances and combustion procedureshave been introduced in Papers I–IV. Theexperiments are summarized in Table 1.
5.1 Combustion arrangements, particlesampling and dilution
Laboratory measurements. In thelaboratory combustion experiments in the batchcombustion (Papers I–II), the appliance wassituated on a scale to enable the measurement offuel mass flow (Figure 2). To mimic a naturaldraught, the combustion gases were led throughan externally insulated steel stack placed below ahood. The draught in the stack was adjusted usinga flue gas fan, changing the location of the hood,and with a damper mimicking natural draughtconditions
Balance
Combustion appliance
Filtration
Stack
Hood
Dilution tunnel
To gasanalyzing rack To
FTIR
To particle samplersTo particle
samplers
ED PRD
T = ThermocoupleP = Pressure sensorPRD = Porous Tube DiluterED = Ejector DiluterFTIR = Fourier Transmission InfraRed Analyzer = Thermal insulation
Air valve
Flue gas fan
Constant volume pump
PT
T
T
T
Figure 2. Experimental setup of the fine particle and gas measurement from the RWC appliance. Thedilution tunnel method and porous tube diluter with ejector diluter are parallel techniques for fine
particle sampling and dilution. The used particle samplers are shown in chapters 5.2–5.6.
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Before particle measurement, the sampleflow was diluted in a dilution tunnel (DT) or aporous tube diluter (PRD) with an ejector diluter(ED, Dekati Ltd.). In the dilution tunnel methodthe dilution air was filtered in three stages, wherea prefilter removes coarse particles, a chemicalfilter removes hydrocarbons and nitrogen oxides,and a postfilter removes fine particles. A partialflow from the stack was led through an externallyinsulated 12 mm steel pipe to the dilution tunnelby the negative pressure in the tunnel.
The total air flow in the tunnel wasadjusted with a constant volume pump (flow rate0–1200 m3 hr1) and the low pressure of thetunnel was controlled with an air valve situatedafter the filters, giving a typical DR of 50 to 300.In two of the laboratory combustion tests, EDswere used (Table 1). This kind of dilution isdiscussed in more detail in Lyyränen et al. (2004)and Wierzbicka et al. (2005).
Field measurement. In the fieldexperiments (Paper III), the measurementdevices were installed inside a box (volume 1.4m3). This box was heated in a van about 1.5hours before and during the measurements with athermostatcontrolled heater (2 kW), and waselevated near the chimney with a telehandler. Thesampling probe was situated in the center of thechimney (at a depth of about 30 cm). Electricitywas produced by a 32 kW diesel generator andpressurized air by a compressor (both on theground).
For particle measurements, a partial flowfrom the stack was led through an externallyinsulated 8 mm steel pipe connected to a specialsampling probe with a 10 µm precyclone. Thesample flow was diluted in two steps. The firstdilution, with filtered (particle, hydrocarbonand waterfree) and heated (180 °C) air, tookplace in the PRD to minimize particle losses andtransformation (Lyyränen et al., 2004). Thesample was further diluted with the ED tostabilize the sample flow through the wholemeasurement system and to ensure good mixingwith dilution air, giving a total (typical) DR of30–70. This particle measurement system wasused in the measurements in Papers III and IV.Temperatures were monitored continuously fromthe combustion appliance, exhaust gas, particle
sample lines, dilution tunnel and laboratory roomair using thermocouples. In addition, otherparameters, such as draught, was monitored.
5.2 Particle number and number sizedistribution measurements
Particle number emissions and numbersize distributions were measured in real time withan Electrical Low Pressure Impactor (ELPI,Dekati Ltd.; Keskinen et al., 1992), and a FastMobility Particle Sizer (FMPS, TSI 3091). In theELPI, the particles are first charged and thenenter a cascade low pressure impactor withelectrically insulated collection stages. Theparticles are collected in the different impactorstages according to their aerodynamic diameter,and the electric charge carried by the particlesinto each impactor stage is measured in real timeby sensitive multichannel electrometers. Thismeasured current signal is directly proportionalto the particle active surface area andaerodynamic size (Keskinen et al., 1992). Theactive surface area can then be converted toparticle number concentration. Because of itswide particle size range (7 nm to 10 µm) and fastresponse time, the ELPI is a suitablemeasurement instrument for the analysis ofunstable concentrations and size distributions inresidential combustion (e.g. Hays et al., 2003;Johansson et al., 2004), and it is also widely usedin the measurement of particle emissions frommotor vehicles (e.g. Ahlvik et al., 1998; Maricqet al., 1999; Tsukamoto et al., 2000) and powerplants (e.g. Moisio, 1999). In this study, both 10and 30 lpm flow rates were used. The sinteredimpactor stages were in most of themeasurements.
In the FMPS, particles are positivelycharged to a predictable level using a coronacharger. The charged particles are thenintroduced to the measurement region near thecenter of a high voltage electrode column andtransported down the column via HEPAfilteredsheath air. A positive voltage is applied to theelectrode, which creates an electric field thatrepels the particles outward according to theirelectrical mobility. Comparable older systems, aDMPS (Differential mobility particle sizer) and
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an SMPS (scanning mobility particle sizer), havebeen widely used in atmosphere and combustionstudies (e.g. Gaegauf et al., 2001; Wierzbicka etal., 2005). In the FMPS, charged particles strikethe respective lownoise electrometers andtransfer their charge. A particle with highelectrical mobility strikes an electrometer nearthe top, whereas a particle with lower electricalmobility strikes an electrometer lower in thestack. This system produces particle sizedistribution measurements with onesecondresolution. The FMPS measures particles in thesubmicron range from 5.6 to 560 nm. The sizerange is smaller than in the ELPI, but the numberof size channels is higher, which gives betterresolution especially for ultrafine particles. TheFMPS operates at a high flow rate (10 lpm) tominimize diffusion losses of ultrafine andnanoparticles. It operates at ambient pressure toprevent evaporation of volatile particles.
The FMPS is also suitable for studies oftransient emission from stacks, boilers, and woodburners, but it has not been used earlier in suchstudies. Because the ELPI is widely used inparticle studies and it gives a wide particle sizerange, while the FMPS gives a good resolutionfor ultrafine particles, the combination of theFMPS and the ELPI gives a good picture of theparticle number concentration and number sizedistributions presented in this thesis.
5.3 Particle mass and mass size distributionmeasurements
In RWC, the obtained emission factor andchemical composition of the particle mass isstrongly dependent on the measurementtechnique used. The most important question is,whether the sampler collects organic material ornot (e.g. Hildemann et al., 1989). The effect ofthe measurement technique on emission factors isdiscussed in more detail in chapter 6.3.
The PM1 samples were collected on filtersfrom diluted gas using a preimpactor (DekatiLtd.) with a cutoff size of 1 µm to ensure theremoval of coarse particles before the filterholders. The PM1 samples for gravimetric andelemental analyses were collected on 47 mmTeflon membrane filters (polytetrafluoroethylene
(PTFE)) (Gelman Scientific, Teflo). The samplesfor organic and elemental carbon analysis werecollected in two parallel lines on 47 mm quartzfiber filters (Pallflex, Tissuequartz). Both lineshad a quartz backup filter, to correct a positivesampling artefact from the adsorption of gaseousorganic compounds on quartz fibre filter material(McDow and Huntzicker, 1990).
Particle mass size distributions weremeasured using a Dekati Low Pressure Impactor(DLPI, Dekati Ltd.). This cascade impactorclassifies airborne particles into 13 size fractions.The particles are collected on 25 mm collectionsubstrates that are weighed before and aftermeasurement to obtain a gravimetric sizedistribution of the particles. The DLPI impactorhas the same design as the impactor used in theELPI. Lowpressure cascade impactors arewidely used in combustion studies (e.g.Kauppinen and Pakkanen, 1990; Johansson et al.,2003; Pagels et al., 2003; Lillieblad et al., 2004;Wierzbicka et al., 2005; Wang et al., 2007). Inthis study, the DLPI was used with a flow rate of10 lpm and a cutoff size ranging from 28 nm to9.84 µm with greased Alfoils as collectionsubstrates.
The filters and Alfoils for gravimetricanalysis were kept for 24 h at a constanttemperature of 20 °C and a relative humidity of40% before weighing, and were weighed using amicrobalance (Mettler Toledo MT1) of 1 µgsensitivity. The weighing procedure is presentedin detail in Tiitta et al. (2002).
5.4 Analysis of particle chemicalcomposition
There are several different methods andprotocols to determine organic carbon (OC) andelemental carbon (EC) concentrations of particlematter. The results are affected by thermalevolution temperatures, pyrolysis corrections,analysis atmosphere compositions, presence orabsence of oxidizing minerals and catalysts,vapor adsorption, and optical pyrolysis correctionmethods. Watson et al. (2005) reviewed differentmethods and concluded that different studies givedifferent results for method comparisons, and thatthe citation of a single comparison study is
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34 Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008)
insufficient to establish comparability. Moresystematic comparisons are needed that holdmost variables constant while varying only a few.In this study, one of the most common methodswas used. The OC, EC and carbonate carbon(CO3 ) fractions were determined from quartzfilter samples with a thermaloptical methodusing a carbon analyzer constructed by SunsetLaboratories. The analyses were performedaccording to the National Institute forOccupational Safety and Health (NIOSH) method5040 (NIOSH, 1999). The OC was measured in ahelium atmosphere at 300 (OC1), 470 (OC2), 610(OC3), 865 (OC4) °C, and the EC in a 2% oxygen98% helium atmosphere in 550, 620, 700, 780,850 and 865 °C. Correction of pyrolyticconversion of OC to EC (Pyrol C) was done bylaser transmission measurement. Correction ofthe gaseous phase organics absorbed in the filtermaterial was performed by analyzing the OCcontent in the backup filter, and subtracting thisamount from that of the front filter OC (Figure 2,Paper III). The CO3 content of the samples wasdetermined indirectly by performing two runs ofeach filter sample and exposing the secondsample punch to HCl vapor, which is presumedto break down the carbonates and, consequently,release the carbonate carbon as CO2. Thus, thedifference between total carbon results gives anestimate of the carbonate carbon content in thesample (Sippula et al., 2007a).
Conversion of the organic carbon (OC) tototal organic matter (OM) requires a conversionof the mass of the organic carbon to the totalmass of the organic compound using a factor thataccounts for the oxygen, hydrogen, and someother elements present. This scale factor rangesbetween 1.2 and 1.4 for typical atmosphericsamples (Gray et al., 1986) and up to 2.0 forwood combustion samples (Turpin and Lim,2001). In this study, a scale factor of 1.8 wasused.
The elemental analyses (Ag, Al, As, B, Ba,Be, Bi, Ca, Cd, Co, Cr, Cu, Fe, K, Li, Mg, Mn,Mo, Na, Ni, Pb, Rb, Sb, Se, Sr, Th, Ti, Tl, U, V,Zn) were performed by Inductively CoupledPlasma Mass Spectrometry (ICPMS, hydrogenfluoride nitric acid dissolution), and anions (Br ,
Cl , F , SO4 , NO3 , PO4 ) were performed byion chromatography (IC) (water elution).
5.5 Analysis of particle morphology
Transmission electron microscopy (TEM)and scanning electron microscopy (SEM) arevery powerful tools to study the shape andmorphology of particles. Equipped with energydispersive spectroscopy (EDS), they also provideinformation about elemental composition. WhileTEM allow a higher resolution down to anatomic scale, SEM usually has a better contrastand leaves more freedom to choose the samplingsubstrate (Burtscher, 2001). Usually very thin,often copper grids, coated with a carbon film, areused for TEM sampling. The quality of this filmand the sampling time play an important role inobtaining a good resolution. If samples are usedfor quantitative analysis of the size distribution,for example, care has to be taken to have a welldefined size dependence of the sampling process.Both electric field and suction sampling are used.The particles in the grid surface may coagulateduring sampling with an electric field, whereas asuction sampler collects single particles.
In this study, particle samples for electronmicroscopy were collected in the stack on holeycarbon copper grids using suction sampling. Thesamples were analysed by a scanning electronmicroscope (Leo DSM 982 Gemini) and atransmission electron microscope (Philips CM200 FEG/STEM operated at 200 kV), includingelemental analyses of the single particles fromTEM samples by EDS.
5.6 Gas measurements
Single gas analyzers are generally used incombustion experiments and are also suitable forRWC measurements. In the laboratorymeasurements the sample for the gas analyzerswas taken straight from the stack through aninsulated and externally heated (180 °C) sampleline. Particles were removed from the sample airby a ceramic filter unit. In the laboratorymeasurements the gaseous compounds weremeasured continuously with an analyzing rack(ABB Cemas Gas Analyzing Rack) for CO, CO2,
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NOx and O2. The organic gaseous substances(OGC, shown as organically bound compounds)were analyzed with a flame ionization detector.The analyzer was calibrated against propane(C3H8). In addition, in the field and laboratorymeasurements the gaseous compounds (NOx, CO,
CO2, H2O, SO2, HCl and 28 calibrated volatileorganic compounds) were measured continuouslywith a Fourier Transform Infrared (FTIR, GasmetTechnologies Ltd.) analyzer. The oxygenconcentration was measured with a separate CrOcell integrated into the FTIR analyzer.
Table 1. The combustion appliances, fuels, test variables and measurements used in the experiments.Used inpublication I II III IV
Test place laboratory laboratory field laboratory
Combustionappliances
MMH; CMH; SS CMH MMH; CMH; S;BO; SS
pellet burner
Fuel birch wood logs birch wood logs mainly birch woodlogs
wood pellet; oat;rape; mixed fuels
Test variables combustionappliances;
batch and log size;combustion phases
operational practice:normal and smouldering
combustion (batch and logsize and restrictedcombustion air)
habitual use ofappliances
fuel; nominal andpartial load
Other combustion processin batch combustion
particle formation field measurementtechnique
combustion processin continuouscombustion
Dilution DT; EDsDR = 50:1–300:1
DTDR = 180:1–330:1
PRD+EDDR = 28:1–72:1
PRD+EDDR = 39:1–75:1
Particle massanalysis
PM1, teflon PM1, teflon;DLPI
PM1, teflon PM1, teflon;DLPI
Particle numberand sizeanalysis
ELPI ELPI; FMPS ELPI: FMPS ELPI; FMPS
Carbon analysis thermaloptical thermaloptical thermaloptical
Ion analysis IC IC IC
Metal analysis ICPMS ICPMS ICPMS
Morphologyanalysis
Suction sampling,SEM; TEM
Gas analysis O2; CO2; CO; NOx;OGC
O2; CO2; CO; NOx; OGC O2; CO2; CO;NOx; SO2; HCl;VOCs (FTIR)
O2; CO2; CO; NOx;SO2; HCl; VOCs
(FTIR)
Other analysis PAH
Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008) 37
6 Results and discussion
6.1 Fine particle and gas emissions fromRWC
Detailed emission factors from literatureand this study are shown in Table 1–3 inAppendix I.
6.1.1 Particle number emissions and numbersize distributions
Number emission results from RWC arescarce and two primary methods have been usedin measurements. Mobility Particle Sizers(FMPS, SMPS and DMPS) measure the numbersize distributions based on particle electricalmobility, whereas the ELPI classifies particlesaccording to their aerodynamic diameter. Resultsfrom these measurements are shown in Table 1 inAppendix I. No significant and systematicdifference between electrical mobility andaerodynamic number emission results wereobserved. Generally, the particle numberemissions from RWC appliances were high. Onaverage, there were no clear differences innumber emissions between different applianceseither. The particle number emission measuredby the ELPI from wood pellets varied from 1.0 ×1014 g kg1 to 8.1 × 1014 g kg1, whereas emissionsfrom the MMH varied between 1.3–5.9 × 1014
kg1 and from metal stove and CMH between2.8–7.0 × 1014 kg1 in laboratory measurements(Appendix I, Table 1; Paper I–IV). In fieldmeasurements, the number emissions werehigher, 8 × 1014 kg1 from MMH (Paper III) and24–42 × 1014 kg1 from CMHs (Paper III), thesame as in laboratory measurements.
The particle number emissions did notcorrespond with the completion of combustion.In the temporary incomplete combustionconditions, e.g. during intermittent operation ofthe pellet burner or in the firing phase of themasonry heaters, the number emissionsincreased. However, it was more common in
heavily incomplete combustion conditions that,the particle number emission was lower ascompared to normal combustion (see Figures 3–5). The particle number emission was related tothe particle size in that incomplete combustionproduced lower particle number emissions butlarger particle sizes than did more completecombustion (Paper I; II; Figures 3 and 4). Inaddition, the particle number emission typicallyincreased from batch to batch despite the bettercombustion conditions with a highercombustion temperature at the end of batchcombustion (Paper I; Figures 3 and 5).
Generally, the particle number sizedistributions were dominated by submicronparticles, and were temporarily unimodals(Figure 6, Paper I; Figure 8, Paper II). Theparticles were very small, and the maxima of thenumber size distributions varied typicallybetween 40 and 200 nm (Papers I–IV). Incontinuous combustion, the number sizedistribution was fairly constant. From woodpellet combustion in the pellet burner, forexample, the geometric mean diameter (GMD)was on average 52 nm when measured by theFMPS, and it varied by only 2–4 nm (standarddeviation) during combustion (Figure 4, PaperIV). In batch combustion, the particle numberdistributions varied between different combustionconditions during the different combustionphases (Figures 3–5). The size distributions werewidest during the firing phase, when the sizes ofthe particles were also larger (Paper I;II).
In Paper I, the largest GMDs wereobserved in the operation of the SS and the CMHappliances, where pyrolysis was very fast,whereas the smallest were observed in theoperation of the MMH, where pyrolysis wasmore controlled. In normal combustion in theCMH in the laboratory experiments, the meanGMD was 56 nm (FMPS), whereas it was clearlyhigher in heavily incomplete combustion, onaverage 118 nm (Figure 7, Paper II).
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38 Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008)
Figure 3. The particle number size distributions, total number emission (Ntot) and particle geometricmean size (GMD) as a function of time from the normal combustion in the CMH (Paper II).
6. RESULTS AND DISCUSSION
Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008) 39
Figure 4. The particle number size distributions, total number emission (Ntot) and particle geometricmean size (GMD) as a function of time from the smouldering combustion in the CMH (Paper II).
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40 Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008)
Figure 5. The particle number size distributions, total number emission (Ntot) and particle geometricmean size (GMD) as a function of time from the MMH in the field experiments (Paper III).
6. RESULTS AND DISCUSSION
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The GMD measured by the FMPS as afunction of GMD measured by the ELPI is shownin Figure 7. Generally, the GMDs were slightlylarger when measured using the ELPI than whenusing the FMPS, indicating that particle effectivedensities were typically above 1 g cm3. In bothdevices, the GMD of particles increased when thecombustion become more incomplete. The GMDfrom the FMPS varied from about 40 to 150 nm,whereas the GMD from the ELPI with sinteredimpaction stages varied from about 50 up to 200nm. The particle sizes were at the same level asin some other comparable studies (e.g. Hedberget al., 2002; Hueglin et al., 1997; Gaegauf et al.,2001; Wierzbicka et al., 2005). Hueglin et al.(1997) and Gaegauf et al. (2001) measuredparticle sizes from 69 to 96 nm and at around 80nm, respectively, from wood pellet combustionby SMPS. The GMD measured by the SMPSfrom a 1 MW grate boiler with pellet combustionwas 79 nm (Wierzbicka et al., 2005).
0
50
100
150
200
0 50 100 150 200ELPI GMD (nm)
FMPS
GM
D (n
m)
Paper IIIPaper II, NCPaper II, SCPaper IV
Figure 6. Particle geometric mean size (GMD)measured by the FMPS as a function of GMD
measured by the ELPI (sintered stages).
6.1.2 PM1 emissions and particle mass sizedistributions
The PM1 emissions from wood pelletcombustion were 0.28 g kg1 (Paper IV). ThePM1 emission from the MMH was slightly higherthan from pellet appliances, mainly below 1 g kg
1. From the CMH, PM1 emissions varied from 0.6
to 3.3 g kg1 (Figure 7; Appendix I, Table 2;Papers II; III). The PM1 emissions from the SSwere clearly higher, 2.7–5.0 g kg1, than fromother appliances (Papers I; III). The PM1 fromsmouldering combustion in the CMH was thehighest, about 10 g kg1 (Paper II).
In Paper I, the PM1 emissions duringdifferent combustion phases and batches weremeasured. The contribution of the firing phasewas the highest from the CMH, 48% of the totalbatch PM1 (0.65 g kg1) in the first batch,increasing to as much as 86% (1.90 g kg1) in thelast batch. In addition, the PM1 emission in thelast batch was 4.5 times larger than in the firstbatch, due mainly to the high particle emissionduring the firing phases (Paper I). In the CMHscombustion is more intensive in a hot firebox, butit also accelerates the gasification of the fuel andincreases emissions from the batches after thefirst batch. At the highest gasification rates, thesupply of air is not adequate, causing incompletecombustion and high PM1 emissions.
The PM1 emissions from pelletcombustion were at similar levels as thosereported recently by Boman et al. (2005) from apellet stove, and PM by Johansson et al. (2004)from pellet burners and boilers. The PM1emissions from stoves (e.g. McDonald et al.,2000: 2.3–7.2 g kg1; Hays et al., 2003: 2.3–10.2g kg1) and cookstoves (Venkataraman and UmaMaheswara Rao, 2001: 0.9–2.8 g kg1) and thePM from fireplaces (e.g. Purvis et al., 2000: 3.3–14.9 g kg1) were slightly higher or the same levelas PM1 emission from the CMH and SS.
When comparing particle emission factors,the sampling, dilution and measurementtechniques need to be considered. Particle lossesand particle transformation are the mostimportant factors that affect particle emissionfactors (see Chapter 6.3). The measurementdevice used may also have an effect on fineparticle emissions. The PM1 emissionsdetermined from DLPI results were 0–25% lowerthan the PM1 determined from filter sampling,probably due to higher particle losses in thecascade impactor as in filter sampling.
The mass size distribution was determinedin a few cases. Over 80% of PM10 particles werebelow 1 µm in aerodynamic size (Paper II). The
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0
4
8
12
Pellet burnersand boilers
Modern MasonryHeaters
ConventionalMasonry Heaters
Sauna Stoves
OG
C a
nd P
M1 e
mis
sion
(g k
g1) PM OGC1
200
400
600
OG
C a
nd P
M1 e
mis
sion
(mg
MJ
1)
Figure 7. Typical OGC and fine particle mass (PM1) emission factors and range of factors fromFinnish combustion appliances. The figure shows data from Appendix I. Error bars indicate the range
of measured values during typical combustion process (not e.g. smouldering combustion).
mass size distributions peaked in one to threemodes (Paper II). In the submicron range, themass size distribution was uni or bimodaldepending on combustion conditions. In somecases, there was also an indication of asupermicron mode at around 1–5 µm particlediameter. This coarse particle mode is typicallycomposed of low volatile ash compounds and itis partially unburnt char (Wiinikka, 2005). TheMMD measured by the DLPI was 164 nm fromwood pellet combustion (Figure 5, Paper IV).From the CMH, the MMD was 243 nm in normalcombustion and clearly higher, 534 nm, insmouldering combustion (Figure 8, Paper II).
In the study of Boman et al. (2005) with apellet stove, the MMD of the fine mode varied inthe range of 117–146 nm. The MMD was higherin three pellet burners (10–15 kW), varying from200–370 nm measured by the DLPI frompelletized, fresh and stored sawdust (Boman etal., 2004). These burners also had higher CO andPM emissions than the pellet appliances usuallydo. Kleeman et al. (1999) using a MOUDIimpactor found that the particle mass sizedistributions from wood smoke from a residential
fireplace had a single mode that peaks atapproximately 100–200 nm particle diameter.
6.1.3 Particle composition
The combustion conditions had cleareffects on PM1 emissions and particle numberand mass size distributions. In addition, thechemical composition of the fine particles duringRWC was closely dependent on the combustionconditions. From wood pellet combustion, over90% of the analyzed PM1 consisted of fine ashcompounds (Figure 8). From RWC, this fine ashis composed mainly of potassium compounds(see Chapter 3.3). The phosphate containingcompounds were an important species in the fineparticles emitted from agricultural fuelcombustion, in contrast to wood fuels (Paper IV;Figure 8). From the pellet burner, the amounts ofincomplete combustion products, EC and POM,were low, typically below 10% (Figure 8). Theseresults are well comparable with previous studiesof wood pellet combustion (Sippula et al.,2007a,b), but slightly higher EC and POM
6. RESULTS AND DISCUSSION
Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008) 43
8 %1 %
45 %31 %
13 %2 %
POM
CO
K
SO
Cl
Other Ash
3
42
2
12 %
4 %2 %
33 %
40 %
7 % 2 % POM
EC
CO
K
SO
PO
Other Ash
3
24
4
2
3
Pellet burner Pellet burner wood pellets (PM1 0.26 g kg1) rape seeds (PM1 0.30 g kg1)
31 %
1 %
8 %
1 %
18 %
38 %
1 %2 % POM
EC
Cl
SO
Al
K
Zn
Other ash
24
55 %41 %
1 % 3 % POM
EC
SO
Al
K
Other ash
24
MMH (field, PM1 0.8 g kg1) SS (field, PM1 4.3 g kg1)
36 %
41 %
13 %
6 %1 % 3 % POM
EC
K
SO
Zn
Other Ash
42
69 %
28 %
1 % 2 % POM
EC
K
SO
Zn
Other Ash
42
CMH NC (PM1 2.3 g kg1) CMH SC (PM1 7.3 g kg1)
Figure 8. Typical chemical compositions of PM1 samples (in mass%) from RWC appliances (PapersIII–IV; normal (NC) and smouldering (SC) combustion calculated from the Frey et al., 2008).
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Figure 9. POM, EC and fine ash emissions as a function of particle mass emission measured from dilutedflue gas. OC is normalized to POM by multiplying by a factor of 1.8. In this study (grey points) the particlemass is PM1 (normal and smouldering combustion values calculated from the Frey et al., 2008), and in the
studies by Schauer et al. (2002) and Fine et al. (2001) the particle mass is PM2.5.
0
4
8
12
0 1 2 3 4 5 6 7 8 9 10
POM
em
issi
on (g
kg1
)Frey et al., 2008 Paper III Paper IV
McDonald et al., 2000 Fine et al., 2002 Schauer et al., 2001
0
1
2
3
0 2 4 6 8 10
EC
em
issi
on (g
kg1
)
0.0
0.3
0.6
0.9
0 2 4 6 8 10Particle mass emission (g kg1)
Fine
ash
em
issi
on (g
kg1
)
6. RESULTS AND DISCUSSION
Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008) 45
contents have also been measured. Wierzbicka etal. (2005) found that the OC fraction from thecombustion of 1–5 MW pellet boilers at mediumload varied from 9 to 14% and the EC variedfrom 18 to 56% of PM1.
From masonry heaters, the fine ashemissions were at a similar level as from pelletcombustion, but the amount of incompletecombustion products, EC and POM, wereconsiderably higher, since 20–30% of PM1 wasash. In addition, EC emission was higher thanPOM emission. In the field measurements, thecomposition of PM1 from the MMH was almostthe same as from the CMH in laboratorymeasurements (Figure 8). However, in separatelyperformed tests on the MMH we observed that asmuch as 50% of the PM1 sample was made up ofash compounds, and that it contained only smallamounts of organics (below 20%). From thesauna stove, the analyzed PM1 was composedmainly of EC (55%) and POM (41%) (Figure 8).From slow heating combustion, the percentage ofPOM even increased: it was 69% of analyzedPM1 in smouldering combustion in Paper II(Figure 8).
In most previous studies, the fine particlesemitted from batchfired appliances have beencomposed mainly of organic material and EC,while the ash content has been relatively low. Forexample, Fine et al. (2001) reported that from40% to almost 100% of fine particle mass wasorganic material in the case of a conventionalfireplace. The fractions of EC in fine particleshave been reported to vary from 1–31 % (Fine etal., 2001; Schauer et al., 2001). In a studyquantifying 350 chemical compounds from woodcombustion, the fraction of POM (OC normalizedby multiplying by 1.2 to compensate for oxyspecies in POM) was more than 80%, the fractionof EC was below 20% and the fraction ofanalyzed ash compounds were below 4% fromthe combustion of soft and hard woods infireplaces and wood stoves (McDonald et al.,2000). Schauer et al. (2001) found that the ashfraction was about 1–5% from the combustion ofpine, oak and eucalyptus in a fireplace. Thus, itseems that the proportion of soot and particularlyfine ash in PM1 is clearly higher from masonryheaters and sauna stoves than from other batch
combustion appliances. In addition, the highfraction of POM seems to represent heavilyincomplete combustion.
Figure 9 summarizes the particlecomposition results from Papers II–IV and fromsome recent studies. In these Papers, the POM(R2 = 0.97) and EC (R2 = 0.93) correlated verywell with analyzed PM1 emissions. When thePM1 emission factor is higher than 0.4 g kg1, thecombustion conditions become more incompleteand both EC and POM increased remarkably,POM emission more strongly (slope 0.71) thanEC (slope 0.34). Other studies also report quitegood correlation between particle mass andPOM. The POM emission in the studies ofMcDonald et al. (2000) and Fine et al. (2001)increased faster than in the studies reported inPapers II–IV, when a similar OC normalization(1.8) was used (Figure 9). The composition of theorganic fraction of PM emissions may bedifferent in the birch wood combustion in thisstudy and the pine, oak, eucalyptus, poplar,hickory etc. combustion, and probably a differentOC normalization should to be used. On the otherhand, the EC emission did not at all correlatewith the PM in the studies of Fine et al. (2001)and Schauer et al. (2002) (Figure 9). However,the EC (i.e. soot) is a tracer of incompletecombustion (see Chapter 3.2) and the ECemission should correspond with theincompleteness of combustion. One of the mostimportant factor that affect the emission factor ofEC is the method and protocol used in the ECanalysis. In particular, the methods used forpyrolysis corrections have significant effects onboth OC and EC results, which probably alsoexplains the differences in the POM resultsbetween this study and other studies.
The fine ash emission had no significantcorrelation with the PM emissions (Figure 9).The vaporization of alkali metals is dependenton the chemical composition of the wood and thereactions of inorganic species (e.g. Sippula et al.,2007a). The combustion temperature also has animportant influence on vaporization, so thatgreater amounts of ash particles are released athigh than at low temperatures (Davidsson et al.,2002; Knudsen et al., 2004). Since the chemicalcomposition of ash does not vary between
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46 Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008)
different pure wood fuels, it seems that thecombustion temperature is the primary factor thataffects the fine ash emission in RWC. Forexample, in Paper II, the low combustiontemperature in smouldering combustion producedlow ash emissions, whereas high temperaturesproduced high emissions (Figure 9). In addition,the amount of ash species increased from batch tobatch due to the increase in the combustiontemperature in subsequent batches (Paper I). InPaper I, similar PM1 emissions from the CMHand the MMH can be explained by the higherrelease of alkali metal particles with the highercombustion temperature from combustion in theMMH (Paper I).
Sippula et al. (2007) found that the higherash content of the bark fuels in the pellet stoveincreased both the fly ash emission and theproducts of incomplete combustion. In addition,it was observed in Paper IV that although thefuel ash content of the other agricultural fuelswere considerably higher than that of wood fuel,the PM1 emission from rape seeds, for example,was surprisingly at the same level as that fromwood pellets. Thus, the chemical composition ofthe fuel ash had a strong effect on the release ofalkali metals. It seems that one important factorexplaining the observed differences in the releaseof ashforming elements is the formation of alkalimetal chlorides, which is seen in the clearcorrelation between the release of chlorine and ofash in the fine particles (Paper IV).
6.1.4 Particle morphology
The study of particle morphology isparticularly important because it providesknowledge of the composition, size and shape ofthe primary particles. However, information onfine particle morphology in RWC is very scarce.
In this study, detailed information on fineparticle morphology during different combustionconditions from CMH was obtained. In SEM andTEM analyses, both large agglomerates (PaperII: Fig. 9d–f, Fig.11) and separate spherical andirregularly shaped particles were observed(Paper II: Fig. 9d–f, Fig. 13, Fig. 14). Largeagglomerates were found to contain mainlycarbon and are considered to be primarily soot
particles. The fine ash particles seemed to occurmainly as separate spherical or irregularly shapedparticles but not as agglomerates. The separateultrafine particles were composed mainly of K, Sand Zn, but also in a lesser extent of C, Ca, Fe,Mg, Cl, P and Na (Paper II: Fig. 12). The largerspherical and irregularly shaped particles werecomposed of same alkali metal compounds, butthey were probably covered with heavy organiccompounds. Separate particles were to someextent connected with agglomerates. From thesmouldering combustion conditions, the surfacesof particles were covered by organic species andthe particles had a more closed (sinteredlike)structure than the particles from normalcombustion (Paper II: Fig. 14). In the separatelyperformed experiments (unpublished results), itwas observed that the fine particles included anumber of irregular, e.g. tubeshaped particles,which are doubtless residual fly ash particlesejected from the grate and carried to the flue gas.
Agglomeratelike particles have beencommon also in other wood combustion studies(e.g. Colbeck et al., 1997; Kocbach et al., 2005;Sippula et al., 2007a). Kochbach et al. (2005)found that while agglomerates from vehicleexhaust were characterised by high levels of Siand Ca, agglomerates from wood smoke werecharacterised by high levels of K. Kochbach etal. (2005) have also reported that the size ofprimary particles of agglomerates was similar tothat found in this study, 37–39 nm (±11 nm).Sippula et al. (2007a) observed that most of theparticles from a pellet stove observed by SEMwere single almost spherical primary (ash)particles, and only a few larger agglomerateparticles were present in the samples. Kochbachet al. (2005) also found large spherical particlesthat were carbon dominated from the lowtemperature combustion of wood.
In summary, it seems that the morphologyof RWC particles is complex and varies betweendifferent combustion conditions. According toparallel particle size distribution and morphologymeasurements in this study, it seems that thereleased ash particles may play an important rolein the formation of the particle number emissionin RWC. In the present experiments, the ultrafinemode in the particle number distributions seemed
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to be determined mainly by the amount ofreleased ash forming material in combustion.Respectively, the shifting of particle size duringdifferent combustion conditions seemed to bedetermined by the amount of condensed organicvapour in the flue gas (Paper II).
6.1.5 Gas emission
The CO and OGC are gas emissions thatindicate the incompleteness of secondarycombustion. The CO and OGC emission factorsare shown in Figures 7 and 10. These emissionswere low in continuous combustion. In PaperIV, the CO emission from the combustion ofwood pellets in a pellet burner was 0.55 g kg1.The CO emissions from agricultural fuels wasabout 3fold those from wood pellet. Wood chipscombustion seemed to increase slightly the COemissions when compared with pellet combustion(Appendix I, Table 3).
The CO emission from pellet combustionwas slightly lower than in the study of Johanssonet al. (2004) (0.6–2.3 g kg1; Appendix I, Table3). The OGC emissions are typically lowfrom continuous combustion, primarily below 0.1g kg1 (Launhardt and Thoma, 2000; Johansson etal., 2004; Appendix I, Table 3).
The CO and OGC emissions were clearlyhigher from batch combustion appliances thanfrom continuous combustion appliances. Thelowest gas emissions were measured fromMMHs, in which the CO emission was 14 g kg1
and OGC 0.4 gC kg1 in the laboratory (Paper I),and CO 28 g kg1 in the field experiments (PaperIII). The CO from the CMHs varied from 22 to68 g kg1 and OGC 1.9 to 6 gC kg1 (Papers I–III). The CO emission values from the CMH(Papers I–III) are well comparable with thosereported in other studies of stoves or fireplaces(e.g. EPA, 1996a; Venkataraman and UmaMaheswara Rao, 2001; Koyuncu and Pinar,2007), whereas OGC emissions were lower thanin other studies (e.g. Bhattacharya et al., 2002;Hübner et al., 2005). Conversely, CO and OGCemissions from the SS are mainly higher thanfrom other appliances. In Paper I, the OGC andCO emissions from the SS were about 24foldand 4fold higher, respectively, than from the
MMH. Extremely high emissions, CO up to 300g kg1 and OGC up to 90 gC kg1, have beenmeasured from oldtype wood log boilers withbig batch size (Johansson et al., 2004). Thesmouldering combustion from the CMHproduced emission factors of 150 g kg1 CO and30 gC kg1 OGC (Paper II).
From the masonry heaters and saunastoves, large variations (10 to 100 times) in gasemission factors were observed from the firing toburn out phases (Paper I). The highest emissionswere caused by the high gasification rate duringthe firing phase that led to an insufficient supplyof air and insufficient mixing of air and fuel. TheOGC and CO emissions were concentrated on thefiring phase and decreased rapidly with timeafterwards (Figure 3, Paper I). However, COemissions were also high during the burn outphases. This is due to the low diffusion rate ofoxygen to the char and the cooling of thecombustion chamber due to the high volume ofexcess air in the combustion chamber. In mostcases the combustion temperature decreasedbelow 800 °C, which is the level needed forcomplete oxidation of CO (Nussbaumer, 2003;Van Loo and Koppejan, 2008).
Regarding other gas emissions, the NOxlevels were relatively low and were similar in allmeasurements for wood fuels (Paper III; IV),since at low temperatures NOx emissions ariseonly from fuel nitrogen. However, the emissionsof NOx, SO2 and HCl from combustion ofagricultural fuels were from 4 to 148fold thoseof wood fuel due to the higher N, S and Clcontent in agricultural fuels (Paper IV).
6.2 Effect of operational practices onemissions
6.2.1 Effect of operation in continuouscombustion
Emissions in continuous combustionappliances were typically low, but increased atpartial or low loads, in the onoff use andcleaning periods. In these cases the emissions ofPM1, EC and POM increased, indicating moreincomplete combustion conditions at partial thanat nominal load (Paper IV). Typically, particle
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48 Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008)
0
60
120
180
Pellet burners andboilers
Modern MasonryHeaters
ConventionalMasonry Heaters
Sauna Stoves
CO
em
issio
n (g
kg1
)
300
600
900
CO
em
issio
n (m
g M
J1
)
Figure 10. Typical CO emission factors and range of factors from Finnish combustion appliances.The figure shows data from Appendix I. Error bars indicate the range of measured values during
typical combustion process (not e.g. smouldering combustion).
size increased during such operation (Paper IV).The effects of burner type (e.g. top, under orsidefeed) on emissions have not been widelystudied, but studies of topfeed pellet stoves andunderfeed pellet burners have not foundsignificant differences in particle number sizedistributions (Tissari et al., 2004a). Operation atpartial load, when the combustion process iscontinuous, has been observed to increaseemissions only slightly (Johansson et al., 2004).A very low load leads to the intermittentoperation of burners, which has a significanteffect on particle and gaseous emissions, and it isdependent on operation type of burner(Johansson et al., 2004). With electrical ignitionin the burner, the emissions were only slightlyhigher in intermitent than continuous operation,because the ignition and burnout phases takevery little time (Paper IV). With the pilot flame,Johansson et al. (2004) found 3, 27, 63foldemissions of PM, CO and OGC, respectively.
Some of the pellet burners have a cleaningoperation as a result of which particle and COemissions increase sharply for a short period(Tissari et al., 2004a). Typically, the cleaningperiods increase the combustion air flow through
the grate and decrease the fuel supplymomentarily what cleans the grate holes (Sippulaet al., 2007a). For particle emissions, thecontribution of the cleaning periods to the wholeemission was less than 10%, but they contributedup to 30% of the whole CO emissions.
6.2.2 Effect of fuel loading on emissions inbatch combustion
Fuel loading had a clear influence onemissions. The use of too large fuel batches orsmall logs (i.e. total area of wood logs) in relationto the size of the heater air intakes causesincomplete combustion. With a large batch size(dry fuel), the gasification rate of the fuelincreases and the supply of air becomesinsufficient (Paper I). When the batch size wasdoubled, all emissions from the CMH increased,except the particle number emission: the OGCemissions were 4.0, CO 2.2 and PM1 1.9 timeshigher (Paper I). For updraught combustion in awood boiler, Johansson et al. (2004) observedthat PM emission from a large fuel load was 4times higher than from a small one. In addition,the use of heat storage decreased CO and OGC
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emissions, 15–28% and 40–50 %, respectively,compared with emissions from a small batch(Johansson et al., 2004). The log size affectedemissions more than did batch size (Paper I).Using equal batch sizes, emissions from smalllogs were 8.7fold for OGC, 2.3fold for CO, 1.4fold for particle number and 4.8fold for PM1higher than from big logs. Wet fuel restricts thecombustion rate of wood. Johansson et al. (2004)investigated the emissions from a ceramic woodboiler with a flue gas fan and a downdraughtboiler using dry and wet wood log fuels. Theyfound that wood fuel with a moisture content of26% givea the lowest emissions, whereas the dryfuel produced slightly higher (1–3fold) and thewet (38%) fuel clearly higher, 7fold CO, 21foldOGC and 4fold PM, emissions. However, it isimportant to note that this kind of findings arevery appliance (case to case) related and therelation between batch sizelog sizefuel moistureon the emissions is very complex and may differbetween different appliances.
6.2.3 Emissions in smouldering combustion
Smouldering combustion is responsible fora significant number of air quality problemslocally and temporarily (Glasius et al., 2006).The most problematic appliances are multifuelboilers, which can burn wood, oil, or pellets, butthey commonly use wood log combustion with anupdraught technique. In addition, light stoves aretypically used with low combustion rates byrestricting the air intakes which lead smoulderingcombustion. Furthermore, too high a burn rate(large fuel batches) causes an insufficient airsupply and smoulderinglike combustion frommasonry heaters and sauna stoves. In Paper II,emissions in conditions of heavily incompletecombustion were studied in more detail. Insmouldering combustion (SC), where small logsand big batches were used, and the air intakeswere closed, the combustion temperature waslower than in normal combustion (NC), and theair supply was clearly inadequate Incompletesecondary combustion of the gaseous organiccompounds in SC increased the emission of OGCto 14fold and POM to 7fold that in NC. Thesmallest effects were observed in CO (3.5fold)
and EC emissions (2fold), which are alsoproducts of incomplete combustion. Because thefine particles were composed mainly of organicmatter in SC, the PM1 emission was also clearlyhigher, about 6fold that in NC. In contrast, theash and particle number emissions were less thanhalf those in NC. Furthermore, the particle size inSC was about 2fold that in NC. In SC, theparticles were covered by organic compounds,due to the condensation of organic matter on thesurfaces of the agglomerates (see 6.1.4).
Johansson et al. (2004) found even higheremissions from the combustion of an oldtypewood log boiler with a big batch size. The COemissions were 300 g kg1, OGC 90 gC kg1 andPM 42 g kg1, whereas in Paper II they were150, 30 and about 10 g kg1, respectively. Jordanand Seen (2005) observed nearly the same PMemission factor as Johansson et al. (2004), asmuch as 40 g kg1 from a wood stove with hooddilution and restricted combustion air (a low burnrate), which is about 4fold the PM1 emissions insmouldering combustion in the CMH in PaperII.
6.3 Effect of sampling and dilution on fineparticle emissions
The measurement methods used can havea strong influence on particle emissions. Organicemissions and particle losses are particularlydependent on the sampling and dilution method.However, there are no general standards ormethods to measure fine particles from smallcombustion devices. In this section, the effects ofsampling and dilution on emissions are discussedbriefly, concentrating on particle mass.
6.3.1 Particle losses
Particle losses are important when the totalPM including coarse (~1–10 µm) and supercoarse (>10 µm) particles are measured. PMlosses are caused by settling, impaction and otherinertial effects and are dependent on particle size(Baron and Willeke, 2001). There were losses ofover 50% for 5 µm particles, and no significantlosses for particles below 1 µm, in two ejectordiluters in series (Wierzbicka et al., 2005). There
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are also significant losses of coarse particles inhood dilution systems, which are widely used inRWC measurements (e.g. EPA Method 5G, NS30582 Method in Norway), but not enoughattention is paid to them. In such systems, theparticle deposition is dependent on the flow ratesof the system, and varies between systems.
Several studies show that the PM fromRWC is totally dominated by fine particles (e.g.Boman et al., 2005). However, coarse and supercoarse particle emissions may play an importantrole in PM. The occurrence of these particles issporadic and is dependent on the combustionappliance. Super coarse particles are residual flyash particles that are ejected from the grate. Forexample, the operation of a sauna stove with ahigh combustion rate and short gas ducts leads toenrichment of coarse and super coarse particles inthe flue gas. In masonry heaters with very longducts (cf. Figure 1a and c in Paper I), the coarseparticle losses in the heaters are high and they notoccur in the flue gas. When the air supplythrough the grate is low in modern masonryheaters or in the slow heating stoves, forexample, the emissions of coarse particles arealso low.
The measurement of coarse and supercoarse particles is very difficult particularly frombatch combustion. Isokineticity is not easy toperform due to variable processes and low flowrates in the chimney. Several parallelmeasurements of diluted PM1 and total PM fromhot flue gas were performed from masonryheaters and sauna stoves (Appendix I, Table 2).According to these unpublished experiments, PMwas not mostly dominated by PM1 and typicallyonly 30–40% of PM was below 1 µm. However,in some cases PM1 from diluted gas was higherthan PM in hot gas. The high fraction of coarseparticles is probably due to the high flow ratesused in Finnish appliances, which leads to theoccurrence of super coarse particles in thechimney.
6.3.2 Transformation of particles
The transformation (nucleation,condensation, coagulation, evaporation) ofparticles is also important in combustion aerosol
sampling (e.g. Turrek, 2004). The methods usedhave a strong influence on the emission results,particularly on organic emissions (Amann andSiegla, 1982; Hildemann et al., 1989; Lipsky andRobinson, 2006). Emissions of EC do not seemto vary with dilution (Lipsky and Robinson,2006).
Dilution is critical for particle sizes in thenucleation mode (Turrek, 2004). When dilutionair is not heated (i.e. is at ambient temperature)and is not dried, nucleation of volatile organiccompounds as well as sulphates and nitrates tendto form new nanoparticles (Shi and Harrison,1999). Nucleation in the dilution has beenobserved from diesel engines, for example, whensulphur rich fuel was used (Vaaraslahti et al.,2004).
In this study it was found that organicvapours do not easily form particles bynucleation despite their high concentration in fluegas (Paper II), but rather condensate on thesurfaces of the existing particles. It also has beenreported that hydrocarbons condense ontoexisting particles rather than form new particlesby nucleation (Pyykönen et al., 2007). The largesurface area of existing particles (both soot andash) during the gastoparticle conversion oforganic vapours can also affect this result.However, in Paper III it was observed inwintertime field experiments that the nucleationof organic compounds does not occur in thefirebox but rather in the chimney when, inaddition to smouldering combustion, theprevailing physical conditions in the flue gas arealso favourable. The occurrence of very smallparticle mode (6–30 nm) from RWC is very rareand has not been reported earlier.
In incomplete combustion conditions thegastoparticle conversion of organic vapours hasa significant effect on PM emission. At lowlevels of dilution, semivolatile species occurmainly in the particle phase, but increasingdilution reduces the concentration of semivolatilespecies, shifting this material to the gas phase inorder to maintain phase equilibrium (Lipsky andRobinson, 2006). For example, a fieldcomparison of a stack sampler with EPA Method5 has shown that this sampler collects about tentimes as much organic material as the hot filter
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portion of the Method 5 train (Hildemann et al.,1989). Purvis et al. (2000) found in fireplace teststhat the temperature at which the particle samplewas collected had a major impact on thePM2.5/PM fraction when the DR was moved from4.3 to 11.0 in the hood dilution method. Hedberget al. (2002) observed that the size distributionswere not severely affected by the dilution ratiosfrom wood stove measurement. Boman et al.(2005) found that the sampling conditions did notinfluence either the emission of PM or theparticle size distribution, but increasedconcentrations of OGC and PAH were observedwhen the dilution ratio was increased from 3 to 7.However, in that study the dilution ratios werelow and the appliance studied was a pellet stove,which has low organic emissions, so it did notaffect the PM. Lipsky and Robinson (2006)concluded in a study measuring the partitioningof semivolatile materials under atmosphericconditions that partitioning theory indicates thatdilution samplers need to be operated in such away that the diluted exhaust achievesatmospheric levels of dilution. They found thattoo little dilution can overestimate fine particlemass emissions, and too much dilution (withclean air) can underestimate them (Lipsky andRobinson, 2006). In order to get maximum PM,the DR should to be about ten (Amann andSiegla, 1982).
In summary, the measurement methodsused have a strong influence on the PM emissionresults, particularly on organic emissions and thefraction of coarse particles. The results from therelation of PM1/PM are inconsistent due to thecoarse particle and POM losses in the samplingand dilution.
6.4 Cases of high and low fine particleemissions from RWC appliances andsuggestions for emission reductionmeasures
Combustion conditions vary significantlybetween different combustion appliances andoperational practices, and this affects emissionfactors remarkably. The factors that influencefine particle and gas emissions from RWC aresummarized in Figure 11. Even a small
difference in the combustion conditions increasesthe emissions, their properties and their effectsremarkably. It should also be noticed that themeasured emission (physical and chemicalcomposition of particles and gases) does notexactly correlate with the emission into theatmosphere. This also leads to the assumptionthat the estimated effects of RWC emissions arenot the same as the real effects (Figure 11).Because of the large number of uncontrolledfactors that affect combustion conditions, theimportance of single factors is not easy todetermine exactly. According to this study, themost important factors that affect high fineparticle emissions are:
1) The overall lack of available oxygen(smouldering combustion). The mostproblematic appliances are multifuel boilers(without heat storage tanks), which can burnwood, oil, or pellets, but are primarily used inwood log combustion with an updraughttechnique. In addition, because of the lowertemporary need for heat, light stoves are typicallyused with low combustion rates by restricting airintakes, which leads to smouldering combustion.In the worst cases, PM emission factors up to 40g kg1 are found. For good combustion quality,short charging intervals with small batch size arerequired. The use of a heat storage tank isadvisable for the combustion of wood log boilers.
2) The conventional combustiontechnique in sauna stoves. Emissions from SSsare high (PM1 up to 5 g kg1) because of theconventional combustion technique. SSs have tooperate with the high combustion rate becausethe need for heat in the sauna room is temporarilyhigh. The firebox is small and secondarycombustion is not possible, so the efficiency islow. In addition, with high gasification rates thesupply of air is clearly insufficient, causingdistinctly incomplete combustion in SSoperation. To reduce emissions of sauna stoves,the combustion technique must be developed orsecondary removal techniques are needed.
3) Too fast pyrolysis and combustionrate in masonry heaters and sauna stoves. Thesize of the air intakes in Finnish heaters isrestricted and the operating temperature in thefirebox is high. Thus, the occurrence of a too
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high gasification rate is typical due to excessivelylarge fuel batches in relation to the size of the airintakes, which leads to an insufficient supply ofair. Thus, controlling the gasification rate via theprimary air supply, log and batch size, as well asfuel moisture content, is important for thereduction of emissions in conventional Finnishappliances.
4) Too low combustion temperature. Inopen fireplaces, cookstoves or campfires, muchheat is often lost to the surroundings due to thelack of radiative heat, which restricts combustiontemperature and increases emissions. The use ofwet fuel also decreases the combustiontemperature. In the ceramic wood log boiler, wetfuel increased emissions 3–4fold, from 0.4–0.6 gkg1 to 1.7 g kg1 (Johansson et al., 2004).
5) Operation of burners at low load.Presently, most pellet and stoker burner systemsdo not have heat storage tanks, and the boiler isset at thermostat control, which results in a cyclicintermittent operation of the burner. Combustionat low loads increases remarkably the emissionsfrom burners that operate with a pilot flame(Johansson et al., 2004: PM1 increased from 0.4up to 1.2 g kg1). In addition, pellet combustionunits with pilot flames should be of a size that
allows continuous combustion. If this is notpossible, these appliances should also beequipped with heat storage tanks.
Emissions in RWC are low:
1) In the continuous combustion of pelletor stokerburners, because the burners have heatcontrol devices and are equipped with effectiveheat exhangers and advanced control devicessuch as an O2sensor. The fuel is fed according tothe heat demand and combusted at a hightemperature in a small grate with staged air.Emissions are typically low (PM1 typically below0.3 g kg1) and fine particles are composedmainly of released alkali metal compounds. Thus,the release of alkali metals, which is dependenton fuel ash content, the chemical composition ofash, and the combustion temperature, are theprimary factors that determine fine particleemissions from continuous combustion.
2) Emissions of modern wood log boilersare also low, PM typically 0.4–0.6 g kg1 due tothe fact that they are equipped with a hot fireboxinsulated with ceramics, advanced controldevices such as an O2sensor, air control andstaged air combustion.
Fuel
Operationalpractices
Operationalconditions
CombustionappliancePhysical properties
(size, moisture, heating value,wood species)Chemical properties(ash composition)
weather conditions, ventilation, draught conditions
appliance type, operational principle,combustion technique,regulation devices,batch/continuous burning
batch size, log size, kindlingpractice
Combustionconditions
Emissions
Measurement
Dilution tooutdoor air
Drifting
Transformation
Exposure
DoseHealtheffects
Measuredemission
Considered effects
Real effects
Climateeffects
Combustion temperature, amount of air supply, air and combustion gas mixing
Measurement techniques and devicesParticle properties:Mass, number, size,morphology, chemicalcomposition
Particle properties
Complete combustion:NO ,SO , ash particlesx 2
Incomplete combustion:CO, OGC, soot, organic particles
Samplinganddilution
Evaluation
(Papers IIV)
(Papers IIV)( )Papers IIV
( )Paper I, II
( )Paper I, III(Paper IV)
( )Paper III
Figure 11. The general picture of the factors influencing fine particle emissions from RWC.
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3) In masonry heaters, hot and closedfirebox surfaces reflect heat back into the flameand create the gas turbulence needed forcomplete combustion. In addition, the secondarycombustion chamber enhances secondarycombustion, and the large mass gives goodefficiency. With an optimal operationaltechnique, emissions from CMHs are low. In thisstudy, in the best cases PM1 was as low as 0.6 gkg1, whereas typical values are about 1.6–1.8 gkg1, and the highest values are 3.3 g kg1 with thesame appliance.
4) In MODERN masonry heaters, incontrast to CMHs, the primary airflow iscontrolled and secondary air is distributed toenvelop the fuel batch e.g. from the small airinlet holes in the grate. These holes enhance themixing of air and combustion gases. Preheating
of secondary air at the expense of the gratetemperature probably decreases the release ofalkali metal compounds, but enhances secondarycombustion. The decreased air supply through thegrate also decreases the flow through the grateand the ejection of coarse particles to the fluegas. The operation at lower overall excess airincreases the combustion temperature. Thus, theemissions caused by incomplete combustionduring pyrolysis are reduced very efficiently andthe composition of the emissions is similar to thatof emissions from continuous combustion from apellet burner, for example. In the best cases, PM1emissions were 0.3–0.5 g kg1, whereas typicalvalues are about 0.7–0.8 g kg1. The effect ofpoor operational practice on emissions in MMHhas not been studied.
Kuopio Univ. Publ. C. Nat. and Environ. Sci. 237:1–63 (2008) 55
7 Summary and conclusionsResidential wood combustion (RWC)
appliances have a high probability of incompletecombustion, producing fine particles andhazardous organic compounds. Generally, thereare several studies on emissions from RWCappliances. However, knowledge on theemissions from woodfired appliances, especiallyconcerning the fine particle emissions and theircomposition during different combustionconditions has been limited. Moreover, therehave not been any scientific studies fromemissions in the Finnish context. Thisinformation is needed to develop low emissioncombustion techniques, to better understand therelation between certain health, and climateeffects and, to put right efforts and measures toreduce these problems.
In this thesis, the fine particle number andmass emissions, particle composition andmorphology, and gas emissions were investigatedfrom a modern (MMH) and conventionalmasonry heaters (CMH), sauna stoves (SS) andpellet burner. The investigation was based onlaboratory and field experiments applyingextensive and unique particle sampling methods.In addition, we obtained a general picture of thesignificance of different factors influencing thefine particle emissions from RWC appliances.
The appliance type, fuel and operationalpractices were found to affect clearly thecombustion conditions and thus, quantity andquality properties of fine particle emissions fromRWC. The measurement methods used have astrong influence on the emission results,particularly on the organic emission and thefraction of coarse particles. In order to getreliable results, the dilution samplers should beapplied with small particle losses and a lowdilution ratio. Total PM is not a reliable factor forcomparison of particle emissions from RWCprimarily due to the occurrence of these particlesin the flue gas is sporadic and dependent on thecombustion appliance, isokineticity is not easy toperform, and there are significant losses of coarseparticles in the measurement in all kind ofmeasurement methods.
The fine particles from wood combustionare formed primarily from the pyrolysis gases(EC, i.e. soot and particle organic matter (POM))and the vaporized alkali metal compounds (i.e.fine ash). In good combustion conditions (e.g. inpellet combustion), the PM1 emission factorswere low, typically below 0.3 g kg1, and over90% of the PM1 consisted of alkali metalcompounds. This is because the burners havewell controlled combustion process and they areequipped with effective heat exhangers andadvanced combustion parameter devices such asan O2sensor. The fuel is fed according to theheat demand and combusted at a hightemperature in a small grate with staged air.
In batch combustion, the combustionconditions are more incomplete and vary duringthe different combustion phases. From the CMHthe typical PM1 values were 1.6–1.8 g kg1, andfrom the SS 2.7–5.0 g kg1, but were stronglydependent on operational practices. With anoptimal operational technique, the PM1 from aCMH was as low as 0.6 g kg1. Respectively, insmouldering combustion the PM1 emissionincreased to 10 g kg1. Fine ash comprised 20–30% of PM1 from the CMH, whereas PM1 fromthe SS was composed mainly of EC (55%) andPOM (41%). From smouldering combustion, thepercentage of POM even increased: it was 69%of analyzed PM1, whereas EC comprized 28% ofPM1. The highest emissions were causedpresumably by the overall lack of availableoxygen which led to incomplete combustionconditions in masonry heaters and sauna stoveswith too fast pyrolysis and too high a fuelcombustion rate. The high emissions from saunastoves were also due to the conventionalcombustion technique with a small firebox andshort ducts without significant secondary airsupply. Respectively, the good secondarycombustion in the MMH reduced the POM andgaseous emissions, but not substantially the ECemission. In the best cases, PM1 emissions were0.3–0.5 g kg1, whereas the typical values areabout 0.7–0.8 g kg1.
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The POM and EC correlated very wellwith the PM1 emissions, whereas fine ashemission was dependent only on the combustiontemperature in RWC. However, the chemicalcomposition of the fuel ash had a strong effect onthe release of alkali metals, when the agriculturalfuels were compared with wood pellet. The PM1emission values from the CMH and pelletappliances were well comparable with thosereported in other studies, whereas the PM1emissions from the MMH were lower, and thosefrom the SS mainly higher, than in other batchcombustion studies.
In the submicron range, the mass sizedistribution was uni or bimodal depending oncombustion conditions. In some cases, there wasalso an indication of a supermicron mode ataround 1–5 µm particle diameter. The mass meandiameter (MMD) was about 160 nm from pelletcombustion, 200–300 nm from the normalcombustion of the CMH, and over 500 nm in thesmouldering combustion of the CMH.
On average, there were no cleardifferences in number emissions betweendifferent appliances and they did also notcorrespond with the completition of combustion.The particle number emission were high, varyingfrom 1.0 × 1014 kg1 to 42 × 1014 kg1. Theparticle number distributions were mainlydominated by ultrafine (<100 nm) particles, butvaried dependent on combustion conditions. Theoccurrence of the nucleation mode in RWC isvery rare. In the wintertime field experiments weobserved that the nucleation of organiccompounds does not occur in the firebox butrather in the chimney when, in addition tosmouldering combustion, the prevailing physicalconditions in the flue gas are favourable.
The particle number emission was relatedto the particle size in such a way that incompletecombustion produced lower number emissionsbut larger particle sizes than more completecombustion. According to parallel particle sizedistribution and morphology measurements inthis study, it seems that the released ash particlesmay play an important role in the formation ofthe particle number emission in RWC. In theCMH experiments, the ultrafine mode in the
particle number distributions seemed to bedetermined mainly by the amount of released ashforming material in combustion. Respectively,the shifting of particle size during differentcombustion conditions seemed to be determinedby the amount of condensed organic vapour inthe flue gas. Thus, it seems that the released ashparticles may play an important role in theformation of the particle number emission also inincomplete combustion conditions. Generally, themorphology of RWC particles is very complexand varies remarkably between differentcombustion conditions and thus, moreinformation is yet needed.
Controlling the gasification rate via theprimary air supply, log and batch size, as well asfuel moisture content, is important for thereduction of emissions in batch combustionappliances. For good combustion quality, shortcharging intervals with small batch size arerequired. To reduce emissions of sauna stoves,the combustion technique or secondary removaltechniques must be developed. In goodcombustion, the release of alkali metals may bereduced with the use of a suitable mixture ofpellet fuels. In addition, the size of pelletcombustion units with pilot flames should besuch that continuous combustion is probable. Ifthis is not possible, these appliances should alsobe equipped with heat storage tanks.
This thesis provided detailed informationabout fine particle emissions from RWC whichcan be used in the development of combustiontechniques that produce fewer fine particles, andalso as the scientific base for further studies. Theresults can also be used to exploit thedevelopment of secondary removal techniquesfor small scale biomass combustion and thedetermining of measurements standard forparticle measurement from RWC. In addition, theuncertainty ranges produced can be exploited inemission inventories. In future, the harmfulnessof different types of particles should also bestudied: in particular, the health effects of fineash particles should be determined. Also basicresearch on particle formation mechanism onspecific combustion conditions will be evenneeded.
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APPENDIX I: EMISSION FACTOR TABLES.Table 1. Fine particle number (N) emission factors (×1014 # kg1) and particle geometric
mean size (GMD, nm) measured in this study (I–IV) and other studies.
This study Other studiesN N GMDae GMDem N N
(ELPI) (FMPS) (ELPI) (FMPS) (ELPI) (SMPS/DMPS)Pellet burners and boilers 8.1IV 9.5IV 62IV 51IV 0.95a,
1.5–2.7b4.9c
Pellet burner, agriculturalfuels
6.3–8.4IV 10–11IV 58–81IV 52–44IV
Pellet stoves 6.7d, 8.7e 16c
Stoker burners, woodpellets
1.0f, 2.4g
Stoker burners, woodchips
1.7g, 2.1f,6.5h
17c
Wood log boilers 3.8i 11c
Modern masonry heater 5.9I, 8III 7.3III 83III 75III 1.3–3.4f
Conventional masonryheater
3.1I, 3.9II,27–31III
3.9II,12–26III
65II,49–75III
56II,54–76III
24–42h 28c
Wood stoves 17III 9III 53III 66III 2.8–7f 4.0j, 9.9c
Sauna stove 12III, 18I 12III 114III 106III 9.8–17.5h
*From smouldering combustion of CMH, N (ELPI) was 1.9 × 1014 # kg1, N (FMPS) 1.4 × 1014 # kg1,GMDae 160 nm and GMDem 118 nm (Paper II). aTissari et al., 2004b; bJohansson et al., 2004; cGaegaufet al., 2001; dTissari et al., 2004a; eSippula et al., 2007a; fTissari et al., 2005a (values are from singlemeasurements in PIPO project); gTissari et al., 2004b; hTissari et al., 2007 (values are from VTTs PUPOfield measurements); iTissari et al., 2005b; jHedberg et al., 2002.
APPENDIX I: EMISSION FACTOR TABLES (CONT.)Table 2. Fine particle mass (PM1) and total particle mass (PM) emission factors (g kg1)
measured in this study (I–IV) and other studies from raw and diluted flue gas.
This study Other ref. Other ref.From diluted gas From diluted gas From hot flue gas
PM1 PM1 Total PMPellet burners and boilers 0.28IV 0.18a 0.2–0.42a,b,c
Pellet/stoker burners,agricultural fuels
0.3–0.5IV 1.48d
Pellet stoves 0.2–0.36e, 1.9–4.0f 1.0b
Stoker burners, woodpellets
0.19g, 0.22h 0.16h, 0.25g
Stoker burners, woodchips
0.24–0.35h,g,i 0.52d, 0.37–0.40h,g,1.3–1.7b,i
Wood log boilers 1.0j 0.5b, 0.4–0.6k,1.7–42m
Modern masonry heater 0.7I,III 0.3–0.5g 1.1–1.2g
Conventional masonryheater
0.6–1.6III, 0.7I,1.8II
0.7–0.8n, 1.9i,2.5–3.3o
1.7–1.9o, 2.5f, 3b,3.1–9.1i
Wood stoves 0.9III 0.5–1.2g, 2.3–10.2p,4–9q, 8.9–13.9f,
5.1–9.5r, 1.3s
1.3b, 2.7–3.3g
Cookstove 0.9–2.8t 2–5u
Sauna stove 2.7III, 5.0I 2.9i 4.5–10.6i
*From smouldering combustion of the CMH, PM1 was about 10 g kg1 (Paper II). aTissari et al., 2004b; bGaegaufet al., 2001; cJohansson et al., 2004; dLaunhardt and Thoma, 2000; eBoman et al., 2005; fEPA, 1996a (range fromdifferent stoves); gTissari et al., 2005a (PM1 are DLPI values from single measurements); hTissari et al., 2004b;iTissari et al., 2007 (PM1 are DLPI values from VTTs PUPO field measurements); jTissari et al., 2005b; kJohanssonet al., 2004 (modern boilers); mJohansson et al., 2004 (old boilers); nTissari et al., 2007 (PUPO pilotmeasurements); oTissari et al., 2007 (PUPO health measurements in summer 2006); pHays et al., 2003; qMcdonaldet al., 2000 (total PM in dilution tunnel); rSchauer et al., 2001; sHedberg et al., 2002; Jordan and Seen, 2005;uVenkataraman and Uma Maweshara Rao, 2001; vOahn et al., 2005.
APPENDIX I: EMISSION FACTOR TABLES (CONT.)
Table 3. CO (g kg1) and OGC (gC kg1) emissions factors measured in this study (I–IV) and otherstudies.
This study* Other studiesCO OGC CO OGC
Pellet burners and boilers 0.55IV 0.6–2.3a, 0.4b 0.02–0.08a, 0.04c
Pellet burners, agriculturalfuels
1.5–1.6IV
Pellet stove 2.5d, 18–24e
Stoker burners, wood pellets 3.7f, 7.6g
Stoker burners, wood chips 2.3c, 6.0–8.8f,26g
0.1c
Wood log boilers 22h, 10–25i,80–300j
5.5h, 0.3–1.7i,13–90j
Modern masonry heater 14I, 28III 0.4I 15–16g
Conventional masonry heater 22I, 42II,29–68III
2.7I, 2.2II,1.9–6III
67–74k, 15–16m,68e, 29–56n
4.6–6.2k,1.1–1.2m
Wood stove 35III 2.3III 25–47g, 28o,47–105e
Sauna stove 55I, 120III 10I, 13III 65–137n
*From smouldering combustion of the CMH, CO was 150 g kg1 and OGC 30 gC kg1 (Paper II). aJohansson et al.,2004; bTissari et al., 2004b; cLaunhardt and Thoma, 2000; dSippula et al., 2007a; eEPA, 1996a (range from differentstoves); fTissari et al., 2004b; gTissari et al., 2005a (values are from single measurements in the PIPO project);hTissari et al., 2005b; iJohansson et al., 2004 (modern boilers); jJohansson et al., 2004 (old boilers); kTissari et al.,2007 (PUPO health measurements in summer 2006); mTissari et al., 2007 (PUPO pilot measurements); nTissari et al.,2007 (VTTs PUPO field measurements); oKoyuncu and Pinar, 2007.
APPENDIX II: CALCULATION OF DR AND EMISSION FACTORS
The raw measurement values were firstdilution corrected. The DR was calculated on thebasis of the concentrations of CO2 (dry) in rawand diluted exhaust gas with the equation
BG,2D,2
BG,2FG,2
COCOCOCO
DR−
−= , (1)
where CO2,D is the CO2 concentration in thediluted gas (CO2sensor: Sensorex Ltd., SensorexSX500D IR sensor, or Cemas Gas AnalyzingRack, ABB Ltd.), CO2,FG is the CO2concentration in the raw flue gas and CO2,BG isthe CO2 concentration in the background dilutionair. In Paper I the DR was calculated by themethod described in Sippula et al., 2007a.
The dilution was corrected with statecorrection and the normalised concentration cn isthen
Ts
on TV
DRCTc+
×==15.273
15.273)0( , (2)
where V is the volume of the sample in itsconditions and Ts is the sample temperature.
The nominal emission values (qe) werecalculated in relation to energy input to thecombustion process (SFS 5624, 1990) accordingto the equation (3)
sne Qkcq ×××= λ . (3)
The airtofuel ratio is
29.209.20O−
=λ , (4)
where O2 is the flue gas oxygen concentration(dry). According to SFS 5624, fuel moisturefactor k is
wu
u
HHHk−
= (5)
where Hu is the net heating value of dry fuel, andHw, the amount of heat consumed in waterevaporation. Hw is determined
vv
vvvw llwH ×
−=×=
γγ
1, (6)
where wv is the mass ratio of water and drysubstance, lv is the evaporation heat of water(2.50 MJ/kg in 0 °C) and v is the mass ratio ofwater and wet fuel. In addition, factor Qs is thedry volume of the flue gas per energy unit formedin the combustion of dry fuel. Os is (almost) thesame for all the solid fuels and therefore a factorof 0.25 m3 MJ1 was used in all experiments.
The emission factor in relation to theamount of fuel used in units of g fuel kg1 (dry),qm, was defined by equation (7)
uem Hqq ×= . (7)
In biomass combustion studies, theconcentration results are presented also asnormalized to 10% (continuous combustionappliances) or 13% (batch combustionappliances) oxygen in the dry flue gas. In thesecases, cn was multiplied by a factor r, that is
2
,2
96.2096.20
OO
r n
−−
= , (8)
where O2 is the flue gas oxygen concentration(dry), O2,n is normalized O2 (e.g. 10 or 13%) and20.96 is the air oxygen concentration.
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