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Journal of Material Cycles and Waste Management

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06.12.2019 | ORIGINAL ARTICLE

Gas and tar generation behavior during flash pyrolysis of wood pellet and plastic

verfasst von: Myo Min Win, Misuzu Asari, Ryo Hayakawa, Hiroyuki Hosoda, Junya Yano, Shin-Ichi Sakai

Erschienen in: Journal of Material Cycles and Waste Management | Ausgabe 2/2020

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Abstract

Fluidized bed gasifiers (FBGs) and gas engines (GEs) could be available as waste-to-energy technology, because most small- and medium-scale municipal solid waste treatment plants have low electricity generation efficiencies. As feedstock composition vary widely based on regional characteristics, clarifying the relationship between gas and tar generation behaviors and feedstock is useful for the design of the GE generation process to predict gas and tar yields and compositions. To understand the synergistic effect of feedstock characteristics in fluidized bed gasification, flash pyrolysis of wood pellet, polyethylene, and polypropylene at 900 °C was conducted. Yields and compositions of gasses and tar from single and co-pyrolysis were investigated. The results reveal that co-pyrolysis increases the gas yield because of oxygenates and moisture present in the wood pellet. Tar yields found to decrease while polycyclic aromatic hydrocarbons (PAHs) are not reduced even during co-pyrolysis. That is because most chain hydrocarbons of tar are converted to C_mH_n gases and PAHs.

Vorheriger Artikel Thermochemical conversion of waste engine oil (WEO) to gasoline-rich crude oil

Nächster Artikel Sustainable E-waste supply chain management with price/sustainability-sensitive demand and government intervention

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PWMI (2019) An introduction to plastic recycling. Plast Waste Manag Inst (in Japanese). https://www.pwmi.or.jp/pdf/panf1.pdf. Accessed 8 Nov 2019

Lee JE, Choi HS, Seo YC (2014) Study of hydrodynamic characteristics in a circulating fluidized bed gasifier for plastic waste by computational fluid dynamics modeling and simulation. J Mater Cycles Waste Manag 16:665–676CrossRef

MoEJ (2017) Japan waste dispoal status and processing situation. Minist Environ Japan (in Japanese). http://www.env.go.jp/recycle/waste_tech/ippan/h27/data/disposal.pdf. Accessed 25 Nov 2018

MoEJ (2007) Technologies to support a sound material-cycle society. Ministry of Environment Japan. https://www.env.go.jp/en/recycle/smcs/arep/2007gs_full.pdf. Accessed 25 May 2017

Al-Salem SM, Antelava A, Constantinou A, Manos G, Dutta A (2017) A review on thermal and catalytic pyrolysis of plastic solid waste (PSW). J Environ Manag 197:177–198CrossRef

Murata K, Makino T (1975) Thermal degradation of polypropylene (in Japanese). Nippon Kagaku Kaishi 1:192–200CrossRef

Takeshi K, Takashi S, Toshio H (1976) Thermal gasification of polypropylene (in Japanese). Nippon Kagaku Kaishi 976:322–327

Collard F-X, Blin J (2014) A review on pyrolysis of biomass constituents: mechanisms and composition of the products obtained from the conversion of cellulose, hemicelluloses and lignin. Renew Sustain Energy Rev 38:594–608CrossRef

Anuar Sharuddin SD, Abnisa F, Wan Daud WMA, Aroua MK (2016) A review on pyrolysis of plastic wastes. Energy Convers Manag 115:308–326CrossRef

10.

Zhang X, Lei H, Chen S, Wu J (2016) Catalytic co-pyrolysis of lignocellulosic biomass with polymers: a critical review. Green Chem 18:4145–4169CrossRef

11.

Wang S, Dai G, Yang H, Luo Z (2017) Lignocellulosic biomass pyrolysis mechanism: a state-of-the-art review. Prog Energy Combust Sci 62:33–86CrossRef

12.

Scheirs J, Kaminsky W (2006) Feedstock recycling and pyrolysis of waste plastics_converting waste plastics into diesel and other fuels. John Wiley Sons Ltd, NJCrossRef

13.

John A. duton e-Education Institute (2018) The Pennsylvania State University Alternative fuels from biomass sources, Chapter 5.1 Biomass Pyrolysis. https://www.e-education.psu.edu/egee439/node/537. Accessed 19 Nov 2018

14.

Zhou H, Wu C, Onwudili JA, Meng A, Zhang Y, Williams PT (2015) Polycyclic aromatic hydrocarbons (PAH) formation from the pyrolysis of different municipal solid waste fractions. Waste Manag 36:136–146CrossRef

15.

Grieco EM, Baldi G (2012) Pyrolysis of polyethylene mixed with paper and wood: interaction effects on tar, char and gas yields. Waste Manag 32:833–839CrossRef

16.

Alvarez J, Kumagai S, Wu C, Yoshioka T, Bilbao J, Olazar M, Williams PT (2014) Hydrogen production from biomass and plastic mixtures by pyrolysis-gasification. Int J Hydrog Energy 39:10883–10891CrossRef

17.

Fujita K, Kumagai S, Kameda T, Yoshioka T (2015) Co-pyrolysis behavior of beech wood and polyethylene mixtures at isothermal temperature. In: Proc 25th Annu Conf Japan Inst Energy, pp 72–73

18.

Kumagai S, Fujita K, Kameda T, Yoshioka T (2016) Interactions of beech wood–polyethylene mixtures during co-pyrolysis. J Anal Appl Pyrolysis 122:531–540CrossRef

19.

Sophonrat N, Sandström L, Johansson AC, Yang W (2017) Co-pyrolysis of mixed plastics and cellulose: an interaction study by Py-GC × GC/MS. Energy Fuels 31:11078–11090CrossRef

20.

Hwang I-H, Kobayashi J, Kawamoto K (2014) Characterization of products obtained from pyrolysis and steam gasification of wood waste, RDF, and RPF. Waste Manag 34:402–410CrossRef

21.

Nedjalkov I, Yoshiie R, Nunome Y et al (2016) Products of high temperature gasification of ABS, PS and PE. J Combust Soc Jpn 186(58):402–410

22.

Matsunaga S, Ueki Y, Yoshiie R, Naruse I (2017) Evaluation of pyrolysis behavior of waste plastic (in Japanese). In: The 28th Annual Conference of Japan Society of Material Cycles and Waste Management, pp 301–302

23.

Bhattacharya P, Steele PH, Hassan EIBM, Mitchell B, Ingram L, Pittman CU Jr (2009) Wood/plastic copyrolysis in an auger reactor: chemical and physical analysis of the products. Fuel 88:1251–1260CrossRef

24.

Ephraim A, Minh DP, Lebonnois D, Peregrina C, Sharrock P, Nzihou A (2018) Co-pyrolysis of wood and plastics: influence of plastic type and content on product yield, gas composition and quality. Fuel 231:110–117CrossRef

25.

Win MM, Asari M, Hayakawa R, Hosoda H, Yano J, Sakai S (2019) Characteristics of gas from the fluidized bed gasification of refuse paper and plastic fuel (RPF) and wood biomass. Waste Manag 87:173–182CrossRef

26.

Önal E, Uzun BB, Pütün AE (2014) Bio-oil production via co-pyrolysis of almond shell as biomass and high density polyethylene. Energy Convers Manag 78:704–710CrossRef

27.

Scott DS, Plskorz J, Radleln D (1985) Liquid products from the continuous flash pyrolysis of biomass. Ind Eng Chem Process Des Dev 24:581–588CrossRef

28.

Shuangning X, Zhihe L, Baoming L, Weiming Y, Xueyuan B (2006) Devolatilization characteristics of biomass at flash heating rate. Fuel 85:664–670CrossRef

29.

Kodera Y (2012) Plastics recycling—technology and business in Japan. In: Waste Manag—An Integr Vision, Luis Fernando Marmolejo Rebellon, IntechOpen, pp 1–26

30.

MoEJ (2012) Manufacturing business survey on refused paper and plastics fuel. RPF; Ministry of Environment Japan (in Japanese), pp 1–78

31.

Japan Plastics Recycling Association (2018) Basic knowledge of plastics recycling (in Japanese). http://www.pwmi.or.jp/. Accessed 26 July 2019

32.

Neeft JPA, Knoef HAM, Zielke U, Sjöström K, Hasler P, Simell PA, Dorrington MA, Thomas L, Abatzoglou N, Deutch S, Greil C, Buffinga GJ, Brage C, Suomalainen M (2001) Guideline for sampling and analysis of tar and particles in biomass producer gases. Version 3.3. Energy project ERK6-CT1999-20002 (Tar protocol)

33.

Qu T-T, Guo W-J, Shen L-H, Xiao J, Zhao K (2011) Experimental study of biomass pyrolysis based on three major components: hemicellulose, cellulose, and lignin. Ind Eng Chem Res 50:10424–10433CrossRef

34.

Ma Z, Chen D, Gu J, Bao B, Zhang Q (2015) Determination of pyrolysis characteristics and kinetics of palm kernel shell using TGA-FTIR and model-free integral methods. Energy Convers Manag 89:251–259CrossRef

35.

Higman C, van der Burgt M (2008) Gasification, 2nd edn. Gulf Professional Publishing, Elsevier

36.

Jin Q, Wang X, Li S, Mikulčić H, Bešenić T, Deng S, Vujanović M, Tan H, Kumfer BM (2017) Synergistic effects during co-pyrolysis of biomass and plastic: gas, tar, soot, char products and thermogravimetric study. J Energy Inst 92(1):108–117CrossRef

37.

Stein SE, Walker JA, Suryan MM, Fahr A (1990) A new path to benzene in flames. In: Twenty-Third Symp Combust, pp 85–90

38.

Tonokura K (2014) Formation of PAH and soot particle in combustion. Earozoru Kenkyu 29(1):5–9

Titel: Gas and tar generation behavior during flash pyrolysis of wood pellet and plastic
verfasst von: Myo Min Win
Misuzu Asari
Ryo Hayakawa
Hiroyuki Hosoda
Junya Yano
Shin-Ichi Sakai
Publikationsdatum: 06.12.2019
Verlag: Springer Japan
Erschienen in: Journal of Material Cycles and Waste Management / Ausgabe 2/2020
Print ISSN: 1438-4957
Elektronische ISSN: 1611-8227
DOI: https://doi.org/10.1007/s10163-019-00949-8

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