Biomass gasification process generates the residual tar, which in turn exerts some negative influence on biomass gasification system. To reduce this harmful influence, an evaluation of the tar properties during the biomass gasification was studied. The chemical composition and pyrolysis behavior of biomass tar were investigated. The complex chemical composition of the tar, which includes phenol derivatives, naphthalene derivatives, other macromolecular aromatic compounds, furans, and other compounds (carbon number from 7 to 14), was established by gas chromatography-mass spectrometry technique. Thermogravimetric analysis was performed with two heating rates (10°C/min and 20°C/min), and Coats-Redfern method was applied to assess the kinetic parameters, i.e., the activation energy (E) and pre-exponential factor (A) of tar thermo-chemical decomposition. The results showed that the main degradation of tar is a two-step process, including a volatilization step at lower temperatures (<105°C) and a pyrolysis step at higher temperatures (105°C-380°C). The application of the Coats-Redfern method revealed a variation trend of the activation energy during the decomposition of tar in a non-isothermal model. It shows that high temperature is more conducive to tar pyrolysis. By adjusting the temperature to control the generation and removal of tar, new approaches are provided for designing and optimizing biomass gasification systems.
Keywords: biomass tar, chemical components, thermogravimetric analysis, kinetics
DOI: 10.25165/j.ijabe.20241703.8362

Citation: Lan W J, Zhou Y L, Liu J X, Wang Y X, Yin D X, Ji J T, et al. Chemical composition evaluation and pyrolysis behavior of biomass tar: Pyrolysis experiment and kinetic studies. Int J Agric & Biol Eng, 2024; 17(3): 230-234.

biomass tar, chemical components, thermogravimetric analysis, kinetics

Inoue N, Tada T, Kawamoto K. Gas reforming and tar decomposition performance of nickel oxide （NiO）/SBA-15 catalyst in gasification of woody biomass. Journal of the Air & Waste Management Association, 2019; 69（4）: 502–512.

Yang H M, Liu J G, Zhang H, Han X X, Jiang X M. Experimental research for biomass steam gasification in a fluidized bed. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 2019; 41（16）: 1993–2006.

Zhang J J, Wang M, Xu S P, Feng Y C. Hydrogen and methane mixture from biomass gasification coupled with catalytic tar reforming, methanation and adsorption enhanced reforming. Fuel Processing Technology, 2019; 192: 147–153.

Xu G Y, Yang P, Yang S X, Wang H X, Fang B Z. Non-natural catalysts for catalytic tar conversion in biomass gasification technology. International Journal of Hydrogen Energy, 2022; 47（12）: 7638–7665.

Guo F Q, Liu Y, Wang Y, Li X L, Li T T, Guo C L. Pyrolysis kinetics and behavior of potassium-impregnated pine wood in TGA and a fixed-bed reactor. Energy Conversion and Management, 2016; 130: 184–191.

Awais M, Li W, Arshad A, Haydar Z, Yaqoob N, Hussain S. Evaluating removal of tar contents in syngas produced from downdraft biomass gasification system. International Journal of Green Energy, 2018; 15（12）: 724–731.

Buentello-Montoya D, Zhang X L, Marques S, Geron M. Investigation of competitive tar reforming using activated char as catalyst. Energy Procedia, 2019; 158: 828–835.

Saleem F, Zhang K, Harvey A. Plasma-assisted decomposition of a biomass gasification tar analogue into lower hydrocarbons in a synthetic product gas using a dielectric barrier discharge reactor. Fuel, 2019; 235: 1412–1419.

Kobayashi J K, Kawamoto K, Kobayashi K. Effect of porous silica on the removal of tar components generated from waste biomass during catalytic reforming. Fuel Processing Technology, 2019; 194: 106104.

Misse S E, Brillard A, Brilhac J-F, Obonou M, Ayina L M, Schönnenbeck C, et al. Thermogravimetric analyses and kinetic modeling of three Cameroonian biomass. Journal of Thermal Analysis and Calorimetry, 2018; 132: 1979–1994.

Mureddu M, Dessì F, Orsini A, Ferrara F, Pettinau A. Air-and oxygen-blown characterization of coal and biomass by thermogravimetric analysis. Fuel, 2018; 212: 626–637.

Li J, Chang G Z, Song K, Hao B L, Wang C P, Zhang J, et al. Influence of coal bottom ash additives on catalytic reforming of biomass pyrolysis gaseous tar and biochar/steam gasification reactivity. Renewable Energy, 2023; 203: 434–444.

Valderrama Rios M L, González A M, Lora E E S, del Olmo O A A. Reduction of tar generated during biomass gasification: A review. Biomass & Bioenergy, 2018; 108: 345–370.

Madav V, Das D, Kumar M, Surwade M, Parikh P P, Sethi V. Studies for removal of tar from producer gas in small scale biomass gasifiers using biodiesel. Biomass & Bioenergy, 2019; 123: 123–133.

Shamsi M, Obaid A A, Farokhi S, Bayat A. A novel process simulation model for hydrogen production via reforming of biomass gasification tar. International Journal of Hydrogen Energy, 2022; 47（2）: 772–781.

Liang S, Guo F Q, Du S L, Tian B L, Dong Y C, Jia X P, et al. Synthesis of Sargassum char-supported Ni-Fe nanoparticles and its application in tar cracking during biomass pyrolysis. Fuel, 2020; 275: 117923.

Li J, Jiao L G, Tao L Y, Chen G Y, Hu J L, Yan B B, et al. Can microwave treat biomass tar? A comprehensive study based on experimental and net energy analysis. Applied Energy, 2020; 272: 115194.

Yin X F, He L M, Syed-Hassan S S A, Deng W, Ling P, Xiong Y M, et al. One-step preparation of a N-CNTs@Ni foam electrode material with the co-production of H2 by catalytic reforming of N-containing compound of biomass tar. Fuel, 2020; 280: 118601.

Chaurasia A. Modeling, simulation and optimization of downdraft gasifier: Studies on chemical kinetics and operating conditions on the performance of the biomass gasification process. Energy, 2016; 116: 1065–1076.

Long Y Q, Li Q H, Zhou H, Meng A H, Zhang Y G. A grey-relation-based method （GRM） for thermogravimetric （TG） data analysis. Journal of Material Cycles and Waste Management, 2018; 20: 1026–1035.

Tan R S, Abdullah T A T, Jalil A A, Isa K M. Optimization of hydrogen production from steam reforming of biomass tar over Ni/dolomite/La2O3 catalysts. Journal of the Energy Institute, 2020; 93（3）: 1177–1186.

Chen G Y, Liu C, Yan B B, Ma W C. Thermal Degradation behaviors and kinetics of biomass tar. Energy Procedia, 2014; 61: 1085–1088.

Yu M M, Masnadi M S, Grace J R, Bi X T, Lim C J, Li Y H. Co-gasification of biosolids with biomass: Thermogravimetric analysis and pilot scale study in a bubbling fluidized bed reactor. Bioresource Technology, 2015; 175: 51–58.

Guo F Q, Dong Y P, Fan P F, Lv Z C, Yang S, Dong L. Catalytic decomposition of biomass tar compound by calcined coal gangue: A kinetic study. International Journal of Hydrogen Energy, 2016; 41（31）: 13380–13389.

Xu T T, Xu F, Hu Z Q, Chen Z H, Xiao B. Non-isothermal kinetics of biomass-pyrolysis-derived-tar （BPDT） thermal decomposition via thermogravimetric analysis. Energy Conversion & Management, 2017; 138: 452–460.

Velázquez- Martí B, Gaibor-Chavez J, Niño-Ruiz Z, Cortes-Rojas E. Development of biomass fast proximate analysis by thermogravimetric scale. Renewable energy, 2018; 126: 954–959.

Mallick D, Poddar M K, Mahanta P, Moholkar V S. Discernment of synergism in pyrolysis of biomass blends using thermogravimetric analysis. Bioresource Technology, 2018; 261: 294–305.

Havilah P R, Sharma P K, Gopinath M. Combustion characteristics and kinetic parameter estimation of Lantana camara by thermogravimetric analysis. Biofuels, 2019; 10（3）: 365–372.

Silva J E, Calixto G Q, de Almeida C C, Melo D M A, Melo M A F, Freitas J C O, et al. Energy potential and thermogravimetric study of pyrolysis kinetics of biomass wastes. Journal of Thermal Analysis and Calorimetry, 2019; 137: 1635–1643.

Umeda K, Nakamura S, Ding L, Yoshikawa K. Biomass gasification employing low-temperature carbonization pretreatment for tar reduction. Biomass & Bioenergy, 2019; 126: 142–149.

Zeng X, Shen M J, Wang F, Ma X H, Hu D D, Wang T T, et al. Generation features and kinetics of gas products in bio-tar catalytic cracking by char for biomass gasification. International Journal of Hydrogen Energy, 2023; 48（82）: 31905–31919.

Zhu X F, Venderbosch R H. Experimental research on gasification of bio-oil derived from biomass pyrolysis. Journal of Fuel Chemistry and Technology, 2004; 32（4）: 510–512. （in Chinese）

Chen G Y, Li J, Cheng Z J, Yan B B, Ma W C, Yao J G. Investigation on model compound of biomass gasification tar cracking in microwave furnace: Comparative research. Applied Energy, 2018; 217: 249–257.

Chen B, Shi Z M, Liu B, Jiang S J, He J Q. Combustion characteristics and combustion kinetics of gasification pine tar acted on by SiO2. Journal of Central South University （Science and Technology）, 2017; 48: 1936–1940.

Wang S L, Zhang Q G, Li J H. Chemical composition of biomass tar and its distillations. Acta Energiae Solaris Sinica, 2006; 27: 647–651.

Xie Q L, Borges F C, Cheng Y L, Wan Y Q, Li Y, Lin X Y, et al. Fast microwave-assisted catalytic gasification of biomass for syngas production and tar removal. Bioresource Technology, 2014; 156: 291–296.

Karaosmanoglu F, Tetik E. Fuel properties of pyrolytic oil of the straw and stalk of rape plant. Renewable Energy, 1999; 16: 1090–1093.

Lan W J, Chen G Y, Zhu X L, Wang X, Wang X T, Xu B. Research on the characteristics of Biomass Gasification in a Fluidized Bed. Journal of the Energy Institute, 2019; 92（3）: 613–620.

Qi G L. Experimental research and numerical simulation of biomass pyrolysis and tar thermal cracking. PhD dissertation. Harbin: Harbin Institute of Technology, 2010; 138 p. （in Chinese）

Ninduangdee P, Kuprianov V I, Cha E Y, Kaewrath R, Youngyuen P, Atthawethworawuth W. Thermogravimetric Studies of Oil Palm Empty Fruit Bunch and Palm Kernel Shell: TG/DTG Analysis and Modeling. Energy Procedia, 2015; 79: 453–458.

Wang J X, Zhao H B. Thermogravimetric analysis of rubber glove pyrolysis by different iso-conversional methods. Waste and Biomass Valorization, 2015; 6（4）: 527–533.

Qiu S J, Chu H L, Zou Y J, Xiang C L, Zhang H Z, Sun L X, et al. Thermochemical studies of Rhodamine B and Rhodamine 6G by modulated differential scanning calorimetry and thermogravimetric analysis. Journal of Thermal Analysis and Calorimetry, 2016; 123（2）: 1611–1618.

Slezak R, Krzystek L, Ledakowicz S. Thermogravimetric analysis coupled with mass spectrometry of spent mushroom substrate and its fractions. Journal of Analytical and Applied Pyrolysis, 2018; 133: 1–8.

Li X T, Grace J R, Lim C J, Watkinson A P, Chen H P, Kim J R. Biomass gasification in a circulating fluidized bed. Biomass & Bioenergy, 2004; 26（2）: 171–193.

Adamu S, Xiong Q G, Bakare I A, Hossain M M. Ni/CeAl2O3 for optimum hydrogen production from biomass/tar model compounds: Role of support type and ceria modification on desorption kinetics. International Journal of Hydrogen Energy, 2019; 44（30）: 15811–15822.

Zhao L X. Experimental study on high efficiency hydrogen production from biomass crude glycerol. PhD dissertation. Tianjin: Tianjin University, 2011; 04. 111 p. doi: 10.7666/d.y2081214. （in Chinese）

Cavattoni T, Garbarino G. Catalytic abatement of biomass tar: a technological perspective of Ni-based catalysts. Rendiconti Lincei, 2017; 28: 69–85.