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Clean Technologies and Environmental Policy

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18-05-2019 | Original Paper

Gasification of waste tires in a circulating fixed-bed reactor within the scope of waste to energy

Authors: Atakan Ongen, Hüseyin Kurtulus Ozcan, Emine Elmaslar Ozbas, Yerbol Pangaliyev

Published in: Clean Technologies and Environmental Policy | Issue 6/2019

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Abstract

Thermochemical decomposition of waste tires was evaluated in order to produce solid and gaseous products within the aim of waste-to-energy concept. Pyrolysis and gasification occur in an “oxygen-starved” environment to “thermally degrade” organic wastes. Waste tires form a large volume of a landfill space that may lead to serious environmental issues and management complexities. Proximate and ultimate analyses reported that approximately 80% carbon in waste tire can be converted to different solid, liquid and gaseous forms for energy gain. Pyrolysis and gasification experiments were carried out in a circulating fixed-bed reactor with cyclone separator at varying temperatures between 600 and 800 °C. Dried air (0.05–0.5 L/min) and pure oxygen (0.01–0.015 L/min) were fed to gasification reactor as partially oxidizing agents. Pyrolysis gasification (PyroGasification—PG) was conducted to produce “syngas” which mainly contains carbon monoxide and hydrogen. One and 4 h of cooking time for the first-step pyrolysis were applied in a nitrogen-rich medium before gasification to enrich carbon amount in fuel. A syngas rich in H₂, CH₄ and CO with a high calorific value of almost 4900 kcal/m³ was obtained in gasification experiments performed with 0.05 L/min of dried air. Volumetric percentages of hydrogen and methane in syngas were around 35% and 40%, respectively. More than 65% mass and 80% volume reductions which are very important for waste management hierarchy and minimization were achieved by gasification of waste tires.

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Alvarez J, Lopez G, Amutio M, Mkhize NM, Danon B, Van der Gryp P, Görgens JF, Bilbao J, Olazar M (2017) Evaluation of the properties of tyre pyrolysis oils obtained in a conical spouted bed reactor. Energy 128:463–474CrossRef

Aslan DI, Parthasarathy P, Goldfarb JL, Ceylan S (2017) Pyrolysis reaction models of waste tires: application of master-plots method for energy conversion via devolatilization. Waste Manag 68:405–411CrossRef

Basu P (2010) Biomass gasification, pyrolysis and torrefaction: practical design and theory, 2nd edn. Academic Press, San Diego

Belgiorno V, Feo G, Rocca DC, Napoli RMA (2003) Energy from gasification of solid wastes. Waste Manag 23:1–15CrossRef

Benedetti V, Patuzzi F, Baratieri M (2018) Characterization of char from biomass gasification and its similarities with activated carbon in adsorption applications. Appl Energy 227:92–99CrossRef

Berrueco C, Esperanza E, Masral FJ, Ceamanos J, Garciá-Bacaicoa P (2005) Pyrolysis of waste tyres in an atmospheric static-bed batch reactor: analysis of the gases obtained. J Anal Appl Pyrolysis 7:245–253CrossRef

Costa GA, Dos Santos RG (2019) Fractionation of tire pyrolysis oil into a light fuel fraction by steam distillation. Fuel 241:558–563CrossRef

Diez O, Maetinez LF, Calvo J, Cara AM (2003) Pyrolysis of tires, influence of the final temperature of the process on emissions and the calorific value of the products recovered. Waste Manag 24:463–469CrossRef

Donatelli A, Iovane P, Molino A (2010) High energy syngas production by waste tyres steam gasification in a rotary kiln pilot plant, experimental and numerical investigations. Fuel 89:2721–2728CrossRef

Elbaba IF, Williams PT (2012) Two stage pyrolysis-catalytic gasification of waste tyres: influence of process parameters. Appl Catal B Environ 125:136–143CrossRef

Fiksel J, Bakshi BR, Baral A, Guerra E, DeQuervain B (2011) Comparative life cycle assessment of beneficial applications for scrap tires. Clean Technol Environ Policy 13:19–35CrossRef

Han J, Li A, Liu D, Qin L, Chen W, Xing F (2018) Pyrolysis characteristic and mechanism of waste tyre: a thermogravimetrymass spectrometry analysis. J Anal Appl Pyrolysis 129:1–5CrossRef

Hita I, Arabiourrutia M, Olazar M, Bilbao J, Arandes JM, Castano P (2016) Opportunities and barriers for producing high quality fuels from the pyrolysis of scrap tires. Renew Sustain Energy Rev 56:745–759CrossRef

Hossain MS, Islama MR, Rahman MS, Kader MA, Haniu H (2017) Biofuel from co-pyrolysis of solid tire waste and rice husk. Energy Procedia 110:453–458CrossRef

Hussein MS, Burra KG, Amano RS, Gupta AK (2017) Temperature and gasifying media effects on chicken manure pyrolysis and gasification. Fuel 202:36–45CrossRef

Islam MR, Haniu H, Beg MRA (2008) Liquid fuels and chemicals from pyrolysis of motorcycle tire waste: product yields, compositions and related properties. Fuel 87:3112–3122CrossRef

Kebritchi A, Firoozifar H, Shams K, Jalali-Arani A (2013) Effect of pre-devulcanization and temperature on physical and chemical properties of waste tyre pyrolytic oil residue. Fuel 112:319–325CrossRef

Kordoghli S, Khiari B, Paraschiv M, Zagrouba F, Tazerout M (2018) Production of hydrogen and hydrogen-rich syngas during thermal catalytic supported cracking of waste tyres in a bench-scale fixed bed reactor. Int J Hydrog Energy. https://doi.org/10.1016/j.ijhydene.2018.09.102 CrossRef

Lopez G, Alvarez J, Amutio M, Mkhize NM, Danon B, van der Gryp P, Görgens JF, Bilbao J, Olazar M (2017) Waste truck-tyre processing by flash pyrolysis in a conical spouted bed reactor. Ener Conver Manag 142:523–532CrossRef

Luo S, Wanga J, Guo X, Liu Z, Sun W (2018) The production of hydrogen-rich gas by wet sludge gasification using waste heat of blast-furnace slag: mass and energy balance analysis. Int J Hydrog Energy. https://doi.org/10.1016/j.ijhydene.2018.10.044 CrossRef

Maroufi S, Mayyas M, Sahajwalla V (2017) Nano-carbons from waste tyre rubber: An insight into structure and morphology. Waste Manag 69:110–116CrossRef

Mingaleeva G, Ermolaev D, Galkeeva D (2016) Physico-chemical foundations of produced syngas during gasification process of various hydrocarbon fuels. Clean Technol Environ Policy 18:297–304CrossRef

Molino A, Donatelli A, Marino T, Aloised A, Rimauroa J, Iovanea P (2018) Waste tire recycling process for production of steam activated carbon in a pilot plant. Resour Conserv Recyc 129:102–111CrossRef

Mozafari A, Tabrizi FF, Farsi M, Mousavi SAHS (2017) Thermodynamic modeling and optimization of thermolysis and air gasification of waste tire. J Anal Appl Pyrolysis 126:415–422CrossRef

Oboirien BO, North BC (2017) A review of waste tyre gasification. J Environ Chem Eng 5:5169–5178CrossRef

Ongen A, Ozcan HK, Arayıcı S (2013) An evaluation of tannery industry wastewater treatment sludge gasification by artificial neural network modeling. J Hazard Mater 263:361–366CrossRef

Ozcan HK, Ongen A, Pangaliyev Y (2016) An experimental study of recoverable products from waste tire pyrolysis. Glob Nest J 18(3):582–590CrossRef

Pangaliyev Y (2014) Derivation of recoverable products from waste tire by pyrolysis/gasification. Master Thesis, Istanbul University Natural Science Institute

Park J, Lee Y, Ryu C (2016) Reduction of primary tar vapor from biomass by hot char particles in fixed bed gasification. Biomass Bioenergy 90:114–121CrossRef

Portofino S, Donatelli A, Iovane P, Innella C, Civita R, Martino M, Matera DA, Russo A, Cornacchia G, Galvagno S (2013) Steam gasification of waste tyre: influence of process temperature on yield and product composition. Waste Manag 33:672–678CrossRef

Singh RK, Ruj B, Jana A, Mondal S, Jana B, Sadhukhan AK, Gupta P (2018) Pyrolysis of three different categories of automotive tyre wastes: product yield analysis and characterization. J Anal Appl Pyrolysis 135:379–389CrossRef

SM 2540 B (1998) Standard methods for the examination of water and wastewater, 20th edn. M.H. Franson, American Public Health Association, Washington

SM 2540 E (1998) Standard methods for the examination of water and wastewater, 20th edn. M.H. Franson, American Public Health Association, Washington

Toledo M, Ripoll N, Céspedes J, Zbogar-Rasic A, Fedorov N, Jovicic V, Delgado A (2018) Syngas production from waste tires using a hybrid filtration reactor under different gasifier agents. Energy Convers Manag 172:381–390CrossRef

Wang M, Zhang L, Li A, Irfan M, Du Y, Di W (2019) Comparative pyrolysis behaviors of tire tread and side wall from waste tire and characterization of the resulting chars. J Environ Manag 232:364–371CrossRef

Williams PT, Brindle AJ (2002) Catalytic pyrolysis of tires: influence of catalyst temperature. Fuel 81:2425–2434CrossRef

Rezaiyan J, Cheremisinoff NP (2005) Gasification technologies, a primer for engineers and scientists. CRC Press, Taylor & Francis, Hardcover, ISBN-10: 0-8247-2247-7

Yu J, Smith JD (2018) Validation and application of a kinetic model for biomass gasification simulation and optimization in updraft gasifiers. Chem Eng Process Intensif 125:214–226CrossRef

Title: Gasification of waste tires in a circulating fixed-bed reactor within the scope of waste to energy
Authors: Atakan Ongen
Hüseyin Kurtulus Ozcan
Emine Elmaslar Ozbas
Yerbol Pangaliyev
Publication date: 18-05-2019
Publisher: Springer Berlin Heidelberg
Published in: Clean Technologies and Environmental Policy / Issue 6/2019
Print ISSN: 1618-954X
Electronic ISSN: 1618-9558
DOI: https://doi.org/10.1007/s10098-019-01705-0

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