Structural and Technological Features of an Installation for Recovery of End-of-life Automobile Tires

Violeta Rasheva; Georgi Komitov; Ivan Binev; Georgi Valtchev

doi:10.1051/e3sconf/202018001016

All issues

Volume 180 (2020)

E3S Web Conf., 180 (2020) 01016

References

Open Access

Issue		E3S Web Conf. Volume 180, 2020 9^th International Conference on Thermal Equipments, Renewable Energy and Rural Development (TE-RE-RD 2020)


Article Number		01016
Number of page(s)		10
Section		Thermal Equipments and Processes
DOI		https://doi.org/10.1051/e3sconf/202018001016
Published online		24 July 2020

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C. Bulei, M. P. Todor, T. Heput, I. Kiss, Directions for material recovery of used tires and their use in the production of new products intended for the industry of civil construction and pavements, Materials Science and Engineering 294 (2018) [Google Scholar]
B. Savary, R. Vincent, Used tire recycling to produce granulates: Evaluation of occupational exposure to chemical agents, Ann. Occup. Hyg., Vol. 55, No. 8 (2011), 931–936 [PubMed] [Google Scholar]
A. Ayanog˘lu, R. Yumrutas, Production of gasoline and diesel like fuels from waste tire oil by using catalytic pyrolysis, Energy (2016) [Google Scholar]
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S. Kordoghli, M. Paraschiv, R. Kuncser, M. Tazerout, M. Prisecaru, F. Zagrouba, I. Georgescu, Managing the Environmental Hazards of Waste Tires, Journal of Engineering Studies and Research, Volume 20, No. 4 (2014) [Google Scholar]
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D. Chakarova, A. Andreev. Energy and exergy analysis of pyrolysis of waste tires, Proceedings of the XXI Scientific Conference EMF’2016, TU-Sofia, (2016), (In Bulgarian) [Google Scholar]

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[1] https://www.consilium.europa.eu/media/41768/12-euco-final-conclusions-en.pdf, European Council meeting (12 December 2019) [Google Scholar]

[2] N. El Bassam, P. Maegaard, and M. L. Schlichting, Current distributed renewable energy rural and urban communities, Distributed Renewable Energies for Off-Grid Communities (2013) [Google Scholar]

[3] G. Lazaroiu, V. Berbece, L. Mihaescu, I. Pisa, G.-P. Negreanu, Biogas production from animal protein waste, an environmental protection technology coupled with energy production, Scientific Works of University of Food TechnologiesPlovdiv, Volume 64, Issue 1, (2017) [Google Scholar]

[4] S. Dichev, Y. Lambrev, Application and perspectives for use of heat pumps in industry, Scientific Works of University of Food Technologies Plovdiv, Vol. XLIII, Issue 3 (1998) (In Bulgarian) [Google Scholar]

[5] G. Raichkov, M. Valchev, M. Georgieva, Permanent ventilation of rooms and buildings factor of healthy comfort, J. Heattecnics, No. 6, Year 5, Book 1, TU-Varna, (2014) (In Bulgarian) [Google Scholar]

[6] Council Directive 1999/31/EC on the landfill of waste, Official Journal of the European Communities (1999) [Google Scholar]

[7] Directive 2006/12/EC of the European Parliament and of the Council on waste, Official Journal of the European Union (2006) [Google Scholar]

[8] Directive 2008/98/EC of the European Parliament and of the Council on waste and repealing certain Directives (2008) [Google Scholar]

[9] M.R. Sebola, P.T. Mativenga, J. Pretorius, A benchmark study of waste tyre recycling in south africa to European union practice, Procedia CIRP 69 (2018), 950–955 [Google Scholar]

[10] Waste Management Act (2012) https://www.moew.government.bg/static/media/ups/tiny/УООП/Законодателство/WASTEMANAGEMENTACT_13.pdf [Google Scholar]

[11] T.A. Mallah, A.R. Sahito, Optimization of castor and neem biodiesel blends and development of empirical models to predict its characteristics, Fuel (2020). [Google Scholar]

[12] K. Georgiev,I. Evtimov, R. Ivanov, Analytical study on wearing of pneumatic tires of wheeled machines, Proceedings of Scientific conference with international participation “Transport, Ecology Sustainable Development”, Varna (2013), 13-17, (In Bulgarian) [Google Scholar]

[13] R. Ivanov, K. Georgiev, G. Kadikyanov, G. Staneva, An experimental research on the wear of truck tire, Poland, SJ Transport Problems, Vol. 10, Issue 4 (2015), 91-98 [CrossRef] [Google Scholar]

[14] K. Georgiev, R. Ivanov, G. Kadikianov, G. Staneva, Analytical study of the effect of tire air pressure on tire wear, Proceedings of International Scientific Conference BulTrans, Sozopol, (2015), 113-116 [Google Scholar]

[15] R.K. Singh, B. Ruj, A.K. Sadhukhan P. Gupta, Energy recovery from tyre waste pyrolysis: product yield analysis and characterization, Energy Recovery Processes from Wastes, Springer Nature Singapore Pte Ltd., (2020) [Google Scholar]

[16] V. Torretta, E.C. Rada, M. Ragazzi, E. Trulli, I.A. Istrate, L.I. Cioca, Treatment and disposal of tyres: two EU approaches. A review, Waste Management 45 (2015) 152–160 [CrossRef] [PubMed] [Google Scholar]

[17] H.-Ho Tsang, Uses of scrap rubber tires, Rubber: types, properties and uses, 2010 Nova Science Publishers, Inc. (2019) [Google Scholar]

[18] C. Bulei, M. P. Todor, T. Heput, I. Kiss, Directions for material recovery of used tires and their use in the production of new products intended for the industry of civil construction and pavements, Materials Science and Engineering 294 (2018) [Google Scholar]

[19] B. Savary, R. Vincent, Used tire recycling to produce granulates: Evaluation of occupational exposure to chemical agents, Ann. Occup. Hyg., Vol. 55, No. 8 (2011), 931–936 [PubMed] [Google Scholar]

[20] A. Ayanog˘lu, R. Yumrutas, Production of gasoline and diesel like fuels from waste tire oil by using catalytic pyrolysis, Energy (2016) [Google Scholar]

[21] P.T. Williams, A.J. Brindle, Fluidised bed catalytic pyrolysis of scrap tyres: Influence of catalyst:tyre ratio and catalyst temperature, Waste Manag. Res. 20 (2002), 546–555 [CrossRef] [PubMed] [Google Scholar]

[22] J.D. Martínez, N. Puy, R. Murillo, T. García, M.V. Navarro, A.M. Mastral, Waste tyre pyrolysis a review, Renew. Sustain. Energy Rev. (2013) [Google Scholar]

[23] D. Perondi B. Santinon Scopel G. Carvalho Collazzo J. Pessutto Silva M. Leoratto Botomé A. Dettmer M. Godinho A.C Faria Vilela, Characteristics of pyrolysis products from waste tyres and spent foundry sand co-pyrolysis Prog. Rubber, Plast. Recycl. Technol. 32 (2016), 213-240 [CrossRef] [Google Scholar]

[24] C.F.S. Rombaldo, A.C.L. Lisbôa, M.O.A. Méndez, A. dos R. Coutinho, Effect of Operating Conditions on Scrap Tire Pyrolysis, Mat. Res. vol. 11 no. 3 (2008) [Google Scholar]

[25] D.Ab. Taleb, H.A. Hamid, R.R.R. Deris, M. Zulkifli, N.A. Khalil, A.N.A. Yahaya, Insights into Pyrolysis of Waste Tire in Fixed Bed Reactor: Thermal Behavior, Materials today: Proceedings February (2020), doi: 10.1016/j.matpr.2020.01.569 [Google Scholar]

[26] M. Ryms, K. Januszewicz, W.M. Lewandowski, E. Klugmann-Radziemska, Pyrolysis Process of Whole Waste Tires as a Biomass Energy Recycling, Ecol Chem Eng S., 20(1) (2013), 93-107 [Google Scholar]

[27] S. Kordoghli, M. Paraschiv, R. Kuncser, M. Tazerout, M. Prisecaru, F. Zagrouba, I. Georgescu, Managing the Environmental Hazards of Waste Tires, Journal of Engineering Studies and Research, Volume 20, No. 4 (2014) [Google Scholar]

[28] G. Komitov, V. Rasheva, I. Binev, I. Kiryakov, Innovation technology for using of disposals automobile tyres, European Journal of technical and natural science, Vol.4, Vienna (2016), 20-22 [Google Scholar]

[29] D. Chakarova, A. Andreev. Energy and exergy analysis of pyrolysis of waste tires, Proceedings of the XXI Scientific Conference EMF’2016, TU-Sofia, (2016), (In Bulgarian) [Google Scholar]