TG-FTIR characterization of coal and biomass single fuels and blends under slow heating rate conditions: Partitioning of the fuel-bound nitrogen

The devolatilization behavior of a bituminous coal and different biomass fuels currently applied in the Dutch power sector for co-firing was experimentally investigated. The volatile composition during single fuel pyrolysis as well as during co-pyrolysis was studied using TG-FTIR characterization with the focus on the release patterns and quantitative analysis of the gaseous bound nitrogen species. It was shown that all investigated biomass fuels present more or less similar pyrolysis behavior, with a maximum weight loss between 300 and 380?textdegreeC. Woody and agricultural biomass materials show higher devolatilization rates than animal waste. When comparing different fuels, the percentage of fuel-bound nitrogen converted to volatile bound-N species (NH3, HCN, HNCO) does not correlate with the initial fuel-N content. Biomass pyrolysis resulted in higher volatile-N yields than coal, which potentially indicates that NOx control during co-firing might be favored. No significant interactions occurred during the pyrolysis of coal/biomass blends at conditions typical of TG analysis (slow heating rate). Evolved gas analysis of volatile species confirmed the absence of mutual interactions during woody biomass co-pyrolysis. However, non-additive behavior of selected gas species was found during slaughter and poultry litter co-pyrolysis. Higher CH4 yields between 450 and 750?textdegreeC and higher ammonia and CO yields between 550 and 900?textdegreeC were measured. Such a result is likely to be attributed to catalytic effects of alkali and alkaline earth metals present in high quantity in animal waste ash. The fact that the co-pyrolysis of woody and agricultural biomass is well modeled by simple addition of the individual behavior of its components permits to predict the mixturetextquoterights behavior based on experimental data available for single fuels. On the other hand, animal waste co-pyrolysis presented in some cases synergistic effects in gas products although additive behavior occurred for the solid phase.

[1]  Chatphol Meesri,et al.  Pyrolytic characteristics of blended coal and woody biomass , 2004 .

[2]  Lars-Erik Åmand,et al.  The temperature's influence on the selectivity between HNCO and HCN from pyrolysis of 2,5-diketopiperazine and 2-pyridone ☆ , 2003 .

[3]  D. W. Pershing Nitrogen oxide formation in pulverized coal flames , 1976 .

[4]  Luis Puigjaner,et al.  Pyrolysis of blends of biomass with poor coals , 1996 .

[5]  U. Jäglid,et al.  The effects of fuel washing techniques on alkali release from biomass , 2002 .

[6]  Chun-Zhu Li,et al.  Formation of NOx and SOx precursors during the pyrolysis of coal and biomass. Part I. Effects of reactor configuration on the determined yields of HCN and NH3 during pyrolysis , 2000 .

[7]  T. Wall,et al.  Nitrogen oxide formation from Australian coals , 1985 .

[8]  Chun-Zhu Li,et al.  LetterInteractions of quartz, zircon sand and stainless steel with ammonia: implications for the measurement of ammonia at high temperatures , 1996 .

[9]  Rafael Kandiyoti,et al.  Co-pyrolysis and co-gasification of coal and biomass in bench-scale fixed-bed and fluidised bed reactors , 1999 .

[10]  Edward Furimsky,et al.  Effect of alkali and alkaline earth metals on nitrogen release during temperature programmed pyrolysis of coal , 1997 .

[11]  John M. Sweeten,et al.  Co-firing of coal and cattle feedlot biomass (FB) fuels. Part II. Performance results from 30 kWt (100,000) BTU/h laboratory scale boiler burner☆ ☆ , 2003 .

[12]  Enrico Biagini,et al.  Devolatilization rate of biomasses and coal–biomass blends: an experimental investigation , 2002 .

[13]  X. Bi,et al.  Overview and some issues related to co‐firing biomass and coal , 2008 .

[14]  M. Aho,et al.  Formation of nitrogen oxides from fuel-N through HCN and NH3: a model-compound study , 1994 .

[15]  Chun-Zhu Li,et al.  Formation of NOx and SOx precursors during the pyrolysis of coal and biomass. Part III. Further discussion on the formation of HCN and NH3 during pyrolysis , 2000 .

[16]  P. R. Solomon,et al.  Sulfur and nitrogen evolution in the Argonne coals. Experiment and modeling , 1993 .

[17]  J. Mackie,et al.  Shock tube pyrolysis of pyridine , 1990 .

[18]  B. Jenkins,et al.  Combustion properties of biomass , 1998 .

[19]  Larry L. Baxter,et al.  Ash deposition during biomass and coal combustion: A mechanistic approach , 1993 .

[20]  John-Chang Chen,et al.  Coal devolatilization during rapid transient heating. 1. Primary devolatilization , 1992 .

[21]  Larry L. Baxter,et al.  Boiler deposits from firing biomass fuels , 1996 .

[22]  C. Blasi,et al.  Thermogravimetric Analysis and Devolatilization Kinetics of Wood , 2002 .

[23]  M. Antal,et al.  Is the Broido-Shafizadeh model for cellulose pyrolysis true? , 1994 .

[24]  D. L. Pyle,et al.  Heat transfer and kinetics in the low temperature pyrolysis of solids , 1984 .

[25]  K. Hein,et al.  Effects of sewage sludge and meat and bone meal Co-combustion on SCR catalysts , 2004 .

[26]  A. Buckley Nitrogen functionality in coals and coal-tar pitch determined by X-ray photoelectron spectroscopy , 1994 .

[27]  P. R. Solomon,et al.  Coal thermal decomposition in an entrained flow reactor: Experiments and theory , 1982 .

[28]  J. A. Howell,et al.  Thermogravimetric analysis of biomass. Devolatilization studies on feedlot manure , 1981 .

[29]  Jouni P. Hämäläinen,et al.  Importance of solid fuel properties to nitrogen oxide formation through HCN and NH3 in small particle combustion , 1993 .

[30]  Yasuhiro Ohshima,et al.  Enhancement of N2 formation from the nitrogen in carbon and coal by calcium , 2001 .

[31]  R. Gadiou,et al.  The behaviour of fuel-nitrogen during fast pyrolysis of polyamide at high temperature , 2000 .

[32]  Aacm Beenackers,et al.  BIOMASS FOR ENERGY AND INDUSTRY , 1998 .

[33]  Freek Kapteijn,et al.  Agglomeration in fluidized beds at high temperatures: Mechanisms, detection and prevention , 2008 .

[34]  L. Baxter Biomass-coal co-combustion: opportunity for affordable renewable energy , 2005 .

[35]  Chun-Zhu Li,et al.  Effects of temperature and molecular mass on the nitrogen functionality of tars produced under high heating rate conditions , 1998 .

[36]  O. Lindqvist,et al.  On the application of surface ionization detector for the study of alkali capture by kaolin in a fixed bed reactor , 2004 .

[37]  Jukka Leppälahti,et al.  Nitrogen evolution from coal, peat and wood during gasification: Literature review , 1995 .

[38]  Panagiotis Grammelis,et al.  Pyrolysis characteristics and kinetics of biomass residuals mixtures with lignite , 2003 .

[39]  RajenderKumar Gupta,et al.  Characterising ash of biomass and waste , 2007 .

[40]  R. Moliner,et al.  Synergetic effects in the co-pyrolysis of coal and petroleum residues: influences of coal mineral matter and petroleum residue mass ratio , 2000 .

[41]  Despina Vamvuka,et al.  Predicting the behaviour of ash from agricultural wastes during combustion , 2004 .

[42]  Hari B. Vuthaluru,et al.  Thermal behaviour of coal/biomass blends during co-pyrolysis , 2004 .

[43]  J. M. Heikkinen,et al.  Characterisation of supplementary fuels for co-combustion with pulverised coal , 2005 .

[44]  Chatphol Meesri,et al.  Lack of synergetic effects in the pyrolytic characteristics of woody biomass/coal blends under low and high heating rate regimes , 2002 .

[45]  K. Kubica,et al.  Devolatilisation characteristics of coal and biomass blends , 2005 .

[46]  Chun-Zhu Li,et al.  Release of HCN, NH3, and HNCO from the Thermal Gas-Phase Cracking of Coal Pyrolysis Tars , 1998 .

[47]  Uwe Schnell,et al.  Behaviour of Gaseous Chlorine and Alkali Metals During Biomass Thermal Utilisation , 2005 .

[48]  Panagiotis Grammelis,et al.  Thermogravimetric studies of the behavior of lignite–biomass blends during devolatilization , 2002 .

[49]  P. Nelson,et al.  Conversion of fuel nitrogen in coal volatiles to NOx precursors under rapid heating conditions , 1991 .

[50]  O. Senneca,et al.  Characterisation of meat and bone mill for coal co-firing , 2008 .

[51]  K. Bartle,et al.  The functionality of nitrogen in coal and derived liquids: An XPS study , 1987 .

[52]  Fred Shafizadeh,et al.  Chemical composition and thermal analysis of cottonwood , 1971 .

[53]  Marek Pronobis,et al.  The influence of biomass co-combustion on boiler fouling and efficiency , 2006 .

[54]  Jun-ichiro Hayashi,et al.  Volatilisation of alkali and alkaline earth metallic species during the pyrolysis of biomass: differences between sugar cane bagasse and cane trash. , 2005, Bioresource technology.

[55]  R. Moliner,et al.  Synergetic effects in the copyrolysis of coal/petroleum residue mixtures by pyrolysis/gas chromatography : Influence of temperature, pressure, and coal nature , 1998 .

[56]  Takayuki Takarada,et al.  Relation between functional forms of coal nitrogen and formation of nitrogen oxide (NOx) precursors during rapid pyrolysis , 1993 .

[57]  R. Font,et al.  Thermal decomposition of meat and bone meal , 2003 .

[58]  Paul T. Williams,et al.  The influence of temperature and heating rate on the slow pyrolysis of biomass , 1996 .

[59]  Jens Beck,et al.  The behaviour of phosphorus in the flue gas during the combustion of high-phosphate fuels , 2006 .