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Biomass Conversion and Biorefinery

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29.01.2022 | Original Article

Comparative study on the co-combustion behavior of torrefied biomass blended with different rank coals

verfasst von: Yanquan Liu, Wenyi Tan, Shaohua liang, Xiaolong Bi, Rongyue Sun, Xiaojun Pan

Erschienen in: Biomass Conversion and Biorefinery | Ausgabe 1/2024

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Abstract

Co-combustion is a practical way to utilize biomass in utility boilers, and torrefaction can effectively improve the intrinsic drawbacks of biomass. In this study, the combustion experiments were conducted in both thermogravimetric analyzer (TGA) and circulating fluidized bed (CFB) test system to evaluate the co-combustion behavior of torrefied cornstalk (TC) blended with different rank coals, including lignite coal (LC), bituminous coal (BC), and anthracite coal (AC). The results indicate that TC can decrease the ignition temperatures of coals, while the burnout temperatures of blends vary with the coal rank. Both synergistic and anti-synergistic interactions occur during the co-combustion, which are affected by the combustion behavior of individual fuels, blending ratio, and combustion stage, etc. In the CFB test system, the CO concentration in flue gas and unburnt carbon content (UBC) in fly ash decrease with the TC blending ratio, which means the coal/TC blends have better combustion performance than coals. Additionally, the effect of TC on the NO_x emissions of blends is related to the coal rank, and the SO₂ emissions decrease with the TC blending ratio due to the low S content in TC. The feeding problem should be paid attention when more than 10% TC is blended with LC and BC. These achievements are helpful for the efficient utilization of biomass in the utility boilers.

Vorheriger Artikel Characterization of selected plant seed oils as anti-foam agents in natural gas treatment units

Nächster Artikel Pyrolysis of lignin (De–alkaline) via TG/DSC–FTIR and TG–MS: pyrolysis characteristics, thermo-kinetics, and gas products

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Wang W, Wen C, Liu T, Li C, Liu H, Liu E, Xu M (2021) Emissions of PM10 from the co-combustion of high-Ca pyrolyzed biochar and high-Si coal under air and oxyfuel atmosphere. Proceedings of the Combustion Institute 38(3):4091–4099CrossRef

Li J, Brzdekiewicz A, Yang W, Blasiak W (2012) Co-firing based on biomass torrefaction in a pulverized coal boiler with aim of 100% fuel switching. Applied Energy 99:344–354CrossRef

Jiang Y, Jeon C (2021) Comparative study on combustion and emission characteristics of torrefied and ashless biomass with coal through the 500 MW tangentially fired boiler simulation. Energy & Fuels 35(1):561–574CrossRef

A. Howell, E. Beagle, E. Belmont, Torrefaction of healthy and beetle kill pine and co-combustion with sub-bituminous coal, Journal of Energy Resources Technology 140 (0420024SI) (2018).

Gil MV, García R, Pevida C, Rubiera F (2015) Grindability and combustion behavior of coal and torrefied biomass blends. Bioresource Technology 191:205–212CrossRef

Han J, Yu D, Yu X, Liu F, Wu J, Zeng X, Yu G, Xu M (2019) Effect of the torrefaction on the emission of PM10 from combustion of rice husk and its blends with a lignite. Proceedings of the Combustion Institute 37(3):2733–2740CrossRef

Yuan H, Yang Q, Wang Y, Gu J, He M, Sun FA (2018) Impact of torrefaction on the fuel properties and combustion characteristics of compost of food waste and sawdust. Energy & Fuels 32(3):3469–3476CrossRef

W. Chen, B. Lin, Y. Lin, Y. Chu, A.T. Ubando, P.L. Show, H.C. Ong, J. Chang, S. Ho, A.B. Culaba, A. Pétrissans, M. Pétrissans, Progress in biomass torrefaction: principles, applications and challenges, Progress in Energy and Combustion Science 82 (2021) 100887.

Sahu SG, Sarkar P, Chakraborty N, Adak AK (2010) Thermogravimetric assessment of combustion characteristics of blends of a coal with different biomass chars. Fuel Processing Technology 91(3):369–378CrossRef

10.

Mundike J, Collard F, Görgens JF (2018) Co-combustion characteristics of coal with invasive alien plant chars prepared by torrefaction or slow pyrolysis. Fuel 225:62–70CrossRef

11.

Yang W, Yang F, Zhang X, Zhu P, Peng H, Chen Z, Che L, Zhu S, Wu S (2021) Preparation of biochar via dry torrefaction of wood meal in a batch reactor under pressure and its co-combustion behavior with anthracite coal. BioResources 16(1):997–1008CrossRef

12.

Kopczyński M, Lasek JA, Iluk A, Zuwała J (2017) The co-combustion of hard coal with raw and torrefied biomasses (willow (Salix viminalis), olive oil residue and waste wood from furniture manufacturing). Energy 140:1316–1325CrossRef

13.

B. Yousaf, G. Liu, Q. Abbas, R. Wang, M. Ubaid Ali, H. Ullah, R. Liu, C. Zhou, Systematic investigation on combustion characteristics and emission-reduction mechanism of potentially toxic elements in biomass- and biochar-coal co-combustion systems, Applied Energy 208 (2017) 142-157.

14.

Alobaid F, Busch J, Stroh A, Ströhle J, Epple B (2020) Experimental measurements for torrefied biomass co-combustion in a 1 MWth pulverized coal-fired furnace. Journal of the Energy Institute 93(3):833–846CrossRef

15.

Eddings EG, Mcavoy D, Coates RL (2017) Co-firing of pulverized coal with Pinion Pine/Juniper wood in raw, torrefied and pyrolyzed forms. Fuel Processing Technology 161:273–282CrossRef

16.

F. Sher, A. Yaqoob, F. Saeed, S. Zhang, Z. Jahan, J.J. Klemes, Torrefied biomass fuels as a renewable alternative to coal in co-firing for power generation, Energy 209 (2020) 118444.

17.

Park S, Jang C, Baek K, Yang J (2012) Torrefaction and low-temperature carbonization of woody biomass: evaluation of fuel characteristics of the products. Energy 45(1):676–685CrossRef

18.

Toptas A, Yildirim Y, Duman G, Yanik J (2015) Combustion behavior of different kinds of torrefied biomass and their blends with lignite. Bioresource Technology 177:328–336CrossRef

19.

Ren X, Sun R, Meng X, Vorobiev N, Schiemann M, Levendis YA (2017) Carbon, sulfur and nitrogen oxide emissions from combustion of pulverized raw and torrefied biomass. Fuel 188:310–323CrossRef

20.

Wu J, Wang B, Cheng F (2017) Thermal and kinetic characteristics of combustion of coal sludge. Journal of Thermal Analysis and Calorimetry 129(3):1899–1909CrossRef

21.

Zhuang X, Song Y, Zhan H, Yin X, Wu C (2019) Synergistic effects on the co-combustion of medicinal biowastes with coals of different ranks. Renewable Energy 140:380–389CrossRef

22.

Liu H, Liang W, Qin H, Wang Q (2016) Synergy in co-combustion of oil shale semi-coke with torrefied cornstalk. Applied Thermal Engineering 109:653–662CrossRef

23.

Zhang N, Wang G, Zhang J, Ning X, Li Y, Liang W, Wang C (2020) Study on co-combustion characteristics of hydrochar and anthracite coal. Journal of the Energy Institute 93(3):1125–1137CrossRef

24.

Zhou C, Liu G, Fang T, Lam PKS (2015) Investigation on thermal and trace element characteristics during co-combustion biomass with coal gangue. Bioresource Technology 175:454–462CrossRef

25.

Zhou C, Liu G, Wang X, Qi C (2016) Co-combustion of bituminous coal and biomass fuel blends: thermochemical characterization, potential utilization and environmental advantage. Bioresource Technology 218:418–427CrossRef

26.

Madanayake BN, Gan S, Eastwick C, Ng HK (2017) Biomass as an energy source in coal co-firing and its feasibility enhancement via pre-treatment techniques. Fuel Processing Technology 159:287–305CrossRef

27.

Yang H, Yan R, Chen H, Zheng C, Lee DH, Liang DT (2006) In-depth investigation of biomass pyrolysis based on three major components: hemicellulose, cellulose and lignin. Energy & Fuels 20(1):388–393CrossRef

28.

S. Deng, H. Tan, B. Wei, X. Wang, F. Yang, X. Xiong, Investigation on combustion performance and ash fusion characteristics of Zhundong coal co-combustion with coal gangue, Fuel 294 (2021) 120555.

29.

Muthuraman M, Namioka T, Yoshikawa K (2010) A comparison of co-combustion characteristics of coal with wood and hydrothermally treated municipal solid waste. Bioresource Technology 101(7):2477–2482CrossRef

30.

Xie C, Liu J, Xie W, Kuo J, Lu X, Zhang X, He Y, Sun J, Chang K, Xie W, Liu C, Sun S, Buyukada M, Evrendilek F (2018) Quantifying thermal decomposition regimes of textile dyeing sludge, pomelo peel, and their blends. Renewable Energy 122:55–64CrossRef

31.

Guo S, Han Y, Wang L, Che D, Liu H, Sun B (2020) Synergistic effects of co-combustion of sewage sludge and corn stalk and the resulting gas emission characteristics. IET Renewable Power Generation 14(9):1596–1605CrossRef

32.

Guo Z, Chen X, Xu Y, Liu H (2015) Study of flow characteristics of biomass and biomass–coal blends. Fuel 141:207–213CrossRef

33.

Ghani WAWA, Alias AB, Savory RM, Cliffe KR (2009) Co-combustion of agricultural residues with coal in a fluidised bed combustor. Waste Management 29(2):767–773CrossRef

34.

Duan L, Sun H, Zhao C, Zhou W, Chen X (2014) Coal combustion characteristics on an oxy-fuel circulating fluidized bed combustor with warm flue gas recycle. Fuel 127:47–51CrossRef

35.

Molcan P, Lu G, Bris TL, Yan Y, Taupin B, Caillat S (2009) Characterisation of biomass and coal co-firing on a 3 MWth Combustion Test Facility using flame imaging and gas/ash sampling techniques. Fuel 88(12):2328–2334CrossRef

36.

Q. Zha, J. Zhao, C.A. Wang, Y. Liu, D. Che, Study on Fuel-N conversion during rapid pyrolysis of anthracite in CO2 at high temperature, Clean Coal Technology and Sustainable Development (2016) 445-451.

Titel: Comparative study on the co-combustion behavior of torrefied biomass blended with different rank coals
verfasst von: Yanquan Liu
Wenyi Tan
Shaohua liang
Xiaolong Bi
Rongyue Sun
Xiaojun Pan
Publikationsdatum: 29.01.2022
Verlag: Springer Berlin Heidelberg
Erschienen in: Biomass Conversion and Biorefinery / Ausgabe 1/2024
Print ISSN: 2190-6815
Elektronische ISSN: 2190-6823
DOI: https://doi.org/10.1007/s13399-022-02368-6

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