A STATE OF ART AND PROSPECTS OF USED PNEUMATIC TIRES MANAGEMENT (REVIEW)

Keywords: solid waste, pneumatic tires, environmental pollution, waste management, recycling tires

Abstract

The basic data on the volume of production of pneumatic tires in the world and in Ukraine are presented. The need to improve the ways of handling pneumatic tires that have lost their con-sumer properties (worn out tires as a result of their intended use and tires rejected as a result of passing quality control during their manufacture) is shown as one of the most dangerous for the environment and promising in terms of using their properties. A detailed classification of methods for handling worn out and defective tires is proposed and a critical analysis of each of them is given. Particular attention is paid to the methods of utilization of tires, in particular, recycling, which makes it possible to efficiently use the secondary raw materials obtained from tires directly for their intended purpose. The features of physical, physicochemical and chemical processing methods, in particular combustion, gasification, pyrolysis of tires and their frag-ments, as well as the prospects for their decomposition under the influence of environmental factors, in particular microorganisms, are also considered. The main ways of solving the prob-lem of tires that have lost their consumer properties in Ukraine are proposed. Bibl. 88, Fig. 2.

Author Biography

I.O. Mikulionok, National Technical University of Ukraine «Igor Sikorsky Kyiv Polytechnic Institute», Kyiv

Doctor of Technical Sciences, Professor

References

Mikulionok I.O., Sokolskyi O.L. (2015). Polimerni materialy i vyroby z nykh (oderzhannia, pereroblennia, vlastyvosti) : Terminologichnyi slovnyk. [Polymeric materials and products from them (production, processing, properties) : Terminological dictionary]. Kyiv: NTUU «KPI», 208 p. — https://ela.kpi.ua/handle/123456789/37632. (Ukr.)

DSTU 2214–93. Vyroby gumovi. Vyprobuvannia. Terminy ta vyznachennia. [Rubber item. Test. Terms and definitions]. Kyiv : Derzhstandart Ukrainy, 1993. 80 p. (Ukr.)

Mikulionok I.O. (2013). Osnonnyye metody ispolzovaniya vyshedshykh iz upotrebleniya avtomobilnykh shin. [Basic Methods for Using Disused Car Tires]. Khimiicheskaya promyshlennost, 90 (4), pp. 202–212. (Rus.)

DSTU 2219:2015. Shyny pnevmatychni. Konstruktsiia. Terminy ta vyznachennia poniat. [Pneumatic tyres. Construction. Terms and definitions of concepts]. Kyiv: UkrNDNTs, 2016. 57 p. (Ukr.)

Haas T., Markl E., Lackner M. (2020). Innovative use of waste tyres: Noise-barriers and geoengineering. World Journal of Advanced Engineering Technology and Sciences, 1 (1), pp. 44–56. — DOI: https://doi.org/10.30574/wjaets.2020.1.1.0024

Ivanov K.S., Surikova T.B. Utilizatsiya iznoshennykh avtomobilnykh shin. [Recycling of used car tires]. — https://www.waste.ru/modules/section/ item.php? itemid=302 (Accessed April 24, 2021). (Rus.)

Titamir O. (2019). Ispolzovannyye avtoshiny: pochemu gosudarstvo ignoriruyet moshchnyy resurs? [Used tires: why does the state ignore a powerful resource?]. Zerkalo nedeli. Ukraina, Iss. 35 (Sept. 21–27, 2019). — https://zn.ua/business/ispolzovannye-avtoshiny-pochemu-gosudarstvo-ignoriruet-moschnyy-resurs-330487_.html (Accessed April 24, 2021). (Rus.)

Ekspluatatsiini normy seredniogo resursu pnevmatychnykh shyn kolisnykh transportnykh zasobiv i spetsialnykh mashin, vykonanykh na kolis-nomu shassi : Nakaz Ministerstva transportu ta zviazku Ukainy vid 20.05.2006, No. 488. [Operational norms of the average resource of pneumatic tires of wheeled vehicles and special machines made on wheeled chassis : Order of the Ministry of Transport and Communications of Ukraine dated 20.05.2006, No. 488]. — https:// zakon.rada.gov.ua/laws/show/z0712-06 (Accessed Apr. 24, 2021). (Ukr.)

Mikulionok I.O. (2021). Stan i perspektyvy povodzhennia z tverdymy polimernymy vidkhodamy. [A state of art and prospects of plastic solid waste management]. Energotokhnologii ta resursozberezhennia, No. 2, pp. 27–48. DOI: 10.33070/etars.2.2021.27. (Ukr.)

GOST R 54095–2010. Resursosberezheniye. Trebovaniya k ekobezopasnoy utilizatsii otrabotavshikh shin. [Resources conservation. Requirements for environmental recovery of used tyres]. Moscow: Standartinform, 2011. 28 p. (Rus.)

GOST R 56828.31–2017. Nailuchsgiye dostupnyye tekhnologii. Resursosberezheniye. Iyerarkhichexkiy poryadok obrashcheniya s otkhodami. [Best available techniques. Resources saving. The hierarchical order of waste treatment]. Moscow.: Standartinform, 2017. 24 p. (Rus.)

Ross D.E. (2020). Use of Waste Tyres in a Circular Economy. Waste Management & Research, 38 (1), pp. 1–3. — DOI: https://doi.org/10.1177/0734242X19895697

Pererabotka pokryshek: dostoinstva i nedostatki. [Tire recycling: advantages and disadvantages]. Resursozberegayushchiye tekhnologii : Ekspress-informatsiya. Moscow: VINITI, 2007. Iss. 19, pp. 6–16. (Rus.)

Mikulionok I.O. (2001). Osnovni metody vukorystannia gumovmisnykh vidkhodiv. [Basic methods of using rubber-containing waste]. Khimichna promyslovist Ukrainy. No. 5, pp. 53–58. (Ukr.)

Mohajerani A., Burnett L., Smith J.V., Markovski S., Rodwell G., Rahman M.T., Kurmus H., Mirzababaei M., Arulrajah A., Horpibulsuk S., Maghool F. (2020). Recycling waste rubber tyres in construction materials and associated environmental considerations : A review. Resources, Conservation and Recycling, 155, Article 104679, 17 p. — DOI: https://doi.org/ 10.1016/j.resconrec.2020.104679

Konkova Ye. (2013). Vtoraya zhizn pokryshki. [The second life of the tire]. Priroda i chelovek. XXI vek, No, 2, pp. 20–22. (Rus.)

Bogdanov V.V. (1989). Udivitelnyy mir reziny. [The amazing world of rubber]. Moscow : Znaniye, 192 p. (Rus.)

Valuyev D.V., Ananyeva O.R. (2011). Perspektivy pererabotki avtomobilnykh pokryshek. [Prospects for the processing of car tires]. Vestnik nauki Sibiri. Series 12. Madhinostroyeniye i transport, No. 1, pp. 699–704. (Rus.)

Ispolzovaniye materialnykh resursov za rubezhom. [Use of material resources abroad: abstract collection]. Moscow: VINITI, 1991. Iss. 7. 86 p. (Rus.)

Gavrilova Yu. Ekologi trebuyut zapretit leb-edey iz shin vo dvorakh. [Environmentalists are de-manding a ban on tire swans in backyards]. — https://kp.ua/life/635478-ekolohy-trebuuit-zapretyt-lebedei-yz-shyn-vo-dvorakh (Accessed April 24, 2021).

Dobrotǎ D., Dobrotǎ G., Dobrescu T. (2020). Improvement of waste tyre recycling technology based on a new tyre markings. Journal of Cleaner Production, 260, Article 121141, 13 p. DOI:10.1016/j.jclepro.2020.121141

Mikulionok I.O. (2014). Mekhanichni, gidromekhanichni i masoonminni protseccy ta obladnannya khimichnoi tekhnologii. [Mechanical, hydromechanical and mass transfer processes and equipment of chemical technology]. Kyiv: NTUU «KPI», 340 p. — https:// ela.kpi.ua/handle/123456789/38169. (Ukr.)

Mikulionok I.O. (2009). Obladnannia i protsessy pererobky termoplastychnykh materialiv z vykorystanniam vtorynnoi syrovyny. [Processes and the equipment of processing of thermoplastics with use of secondary raw materials]. Kyiv: NTUU «KPI». 264 p. — https://ela.kpi.ua/handle/123456789/28259. (Ukr.)

Мікульонок І.О. (2003). Obladnannia dlia mekhanichnogo ruinuvannia polimer- ta elastomervmisnykh vidkhodiv. [Equipment for mechanical destruction of polymer- and elastomer-containing waste]. Khimiia ta khimichni tekhnologii, No. 1, pp. 131–134. (Ukr.)

Мікульонок І.О. (2013). Modeliuvannia obladnannia tekhnologichnykh lilii dlia pereroblennia plastmas i gumovykh sumishei na bazi valkovykh mashin. [Modeling of the equipment of technological lines for processing of plastics and rubber mixes on the basis of rolling machines]. Kyiv: NTUU «KPI». 244 p. — https://ela.kpi.ua/handle/123456789/37520 (Ukr.)

Satonin A.V., Dobronosov Yu.K., Yemchenko Ye.A., Borisenko A.V., Gavrilchenko Ye.Yu. (2006). Tekhnologii i oborudovaniye po utilizatsii krupnogabaritnykh shin. [Technologies and equipment for recycling large tires]. Vostochno-Yevropeyskiy zhurnal peredovykh technologiy, No. 6/1(18), pp. 82–85. (Rus.)

Solovyev Ye.M., Kuznetsova I.A., Tigina O.V. (1987). Oborudovaniye dlya pererabotki otkhodov rezinivoy promyshlennosti. [Equipment for the processing of rubber industry waste]. Moscow : TsINTIKhIMNEFTE- MASh, 36 p. (Rus.)

Kroll L., Hoyer S. (2019). Zero-waste production: Technology for the in-house recycling of technical elastomers. Procedia Manufacturing, 33, pp. 335–342. DOI:10.1016/j.promfg.2019.04.041

Ispolzovaniye materialnykh resursov za rubezhom. [Use of material resources abroad: abstract collection]. Moscow: VINITI, 1990. Iss. 6. 74 p. (Rus.)

Drozdovskiy V.F. (1990). Polucheniye rezinivoy kroshki iz amortizovannykh shin pri nizkikh temperaturakh. [Production crumb rubber from amortized tires at low temperatures]. Moscow: TsNIITEneftekhim, 62 p. (Seriya «Proizvodstvo shin»; Iss. 7). (Rus.)

Mikulionok I.O. (2016). Structural Implementation of the Process of Elasto-Deformation Shredding of Rubber-Containing Wastes (Survey of Patents). Chemical and Petroleum Engineering, 51 (9–10), pp. 604–608. DOI: 10.1007/s10556-016-0093-9

Mikulionok I.O., Lukach Yu.Ye. (2007). Osobennosti konstruktivnogo ispolneniya rotornykh izmelchiteley dlya rezino- I polimersoderzhash-chikhotkhodov (Obzor). [Features of design of rotary grinders for rubber and polymer-containing waste (Review)]. Ecotekhnologii i resursosberezheniye, No. 3, pp. 69–72. (Rus.)

Hoyer S., Kroll L., Sykutera D. (2020). Technology comparison for the production of fine rubber powder from end of life tyres. Procedia Manufacturing, 43, pp. 193–200. DOI: 10.1016/j.promfg.2020.02.135

Adhikari J., Das A., Sinha T., Saha P., Kim J.K. (2019). Grinding of Waster Rubber. Ch. 1. P. 1–23. In: Rubber Recycling: Challenges and Developments. J.K. Kim, P. Saha, S. Thomas, J.T. Haponiuk, M.K. Aswathi (eds.). Croydon: CPI Group (UK) Ltd, 337 p.

Trofimova G.M., Novikov D.D., Kompaniyest L.V., Medintseva T.I., Yan Yu.B., Prut E.B. (2000). Vliyaniye metoda izmelcheniya na strukturu rezinivoy kroshki. [Influence of the grinding method on the structure of crumb rubber]. Vysokomolekulyarnyye soedineniya. Seriya A, 42 (7), pp. 1238–1245. (Rus.)

Mikulionok I.O. (2011). Pretreatment of Recycled Polymer Raw Material. Russian Journal of Applied Chemistry, 83 (6), pp. 1105−1113. DOI: 10.1134/S1070427211060371

Fazli A., Rodrigue D. (2020). Waste Rubber Recycling: A Review on the Evolution and Properties of Thermoplastic Elastomers. Materials, 13 (3), pp. 782–812. DOI: 10.3390/ma13030782

Leonov D.I., Leonov I.V. (1999). Analiz sposobov izmelcheniya iznoshennykh shin. [Analysis of methods of grinding worn tires]. Mashinostroitel, No. 8, pp. 28–29. (Rus.)

Bowles A., Fowler G.D., O’Sullivan C., Parker

K. (2020). Sustainable rubber recycling from waste tyres by waterjet: A novel mechanistic and practical analysis. Sustainable Materials and Technologies, 25, Article e00173, 15 p. DOI: https://doi.org/10.1016/j.susmat.2020.e00173

Perlina Zh.V., Veselov I.V. (2009). O primenenii regenerate v shinnykh rezinakh. [About application of regenerate in tire tires]. 20-y Yubileynyy simpozium «Problemy shin i rezinokordmykh kompozitov» (October 12–16, 2009). Moscow: NIIShP, Vol. 2, pp. 121–125. (Rus.)

Ispolzovaniye materialnykh resursov za rubezhom. [Use of material resources abroad: abstract collection]. Moscow: VINITI, 1990. Iss. 3. 62 p. (Rus.)

Al-Bared M.A.M., Marto A., Latifi N. (2018). Utilization of Recycled Tiles and Tyres in Stabilization of Soils and Production of Construction Materials — A State-of-the-Art Review. KSCE Journal of Civil Engineering, 22, pp. 3860–3874. DOI: https:// doi.org/10.1007/s12205-018-1532-2

Barišić I., Zvonarić M., Grubeša I.N., Šurdonja S. (2021). Recycling waste rubber tyres in road construction. Archives of Civil Engineering, 67 (1), pp. 499–512. DOI: 10.24425/ace.2021.136485

Rahman M.T., Mohajerani A., Giustozzi F. (2020). Recycling of Waste Materials for Asphalt Concrete and Bitumen: A Review. Materials, 13 (7), pp. 1495–1514. DOI: 10.3390/ma13071495

Chiu C.-T., Lu L.-C. (2007). A laboratory study on stone matrix asphalt using ground tire rubber. Construction and Building Materials, 21 (5), pp. 1027–1033. DOI: https://doi.org/10.1016/j.conbuildmat.2006.02.005

Senin M.S., Shahidan S., Leman A.S., Othman N., Shamsuddin S., Ibrahim M.H.W., Mohd Zuki S.S. (2017). The durability of concrete containing recycled tyres as a partial replacement of fine aggregate. IOP Conference Series: Materials Science and Engineering, 271, Article 012075, 8 p. DOI: 10.1088/1757-899x/ 271/1/012075

Almaleeh A.M., Shitote S.M., Nyomboi T. (2017). Use of waste rubber tyres as aggregate in concrete. Journal of Civil Engineering and Construction Technology, 8 (2), pp. 11–19. DOI: 10.5897/ JCECT2016.0421

Medina N.F., Medina D.F., Hernández-Olivares F., Navacerrada M.A. (2017). Mechanical and thermal properties of concrete incorporating rubber and fibres from tyre recyclingю Construction and Building Materials, 144, pp. 563–573. DOI: http://dx.doi.org/10.1016/j.conbuildmat.2017.03.196

Makarova Ye.I., Benza Ye.V., Gerke S.G., Abu-Khasan M., Starinets M.S. (2006). Utilizatsiya otrabotannykh rezinovykh pokryshek. [Disposal of waste rubber tires]. Novyye issledovaniya v materialovedenii i ekologii, No. 6, pp. 38–39. (Rus.)

Foti D., Adamopoulos S., Voulgaridou E., Passialis C., Voulgaridis E. (2020). Compression strength properties of gypsum matrix composites with recovered fibrous scrap materials from post-consumer tyres. International Journal of Materials and Product Technology, 61 (1), pp. 53–67. DOI: 10.1504/ IJMPT.2020.10033164

Sol-Sánchez M., Moreno-Navarro F., Saiz L., Rubio-Gámez M.C. (2019). Recycling waste rubber particles for the maintenance of different states of railway tracks through a two-step stoneblowing process. Journal of Cleaner Production, Article JCLP 118570, 23 p. DOI: https://doi.org/10.1016/j.jclepro.2019.118570

Thai Q.B., Chong R.O., Nguyen P.T.T., Le D.K., Le P.K., Phan-Thien N., Duong H.M. (2020). Recycling of waste tire fibers into advanced aerogels for thermal insulation and sound absorption applications. Journal of Environmental Chemical Engineering, 8, Article 104279, 9 p. DOI: https://doi.org/10.1016/j.jece.2020.104279

Makarov V.M., Drozdovskiy V.F. (1986). Ispolzovaniye amortizovannykh shin i otkhodov proizvodstva rezinovykh izdeliy. [Use of amortized tires and waste from rubber production]. Leningrad : Khimiya, 248 p. (Rus.)

Mikulionok I.O. (2015). Tekhnologichni osnovy pereroblennia polimeriv, plastmas i gumovykh sumishei. [Technological bases of processing of polymers, plastics and rubber mixtures]. Kyiv: NTUU «KPI». 312 p. (Ukr.)

Mikulionok I.O. (2020). Tekhnologichni osnovy pereroblennia polimernykh materialov. [Technological bases of processing of polymeric materials]. Kyiv: NTUU «KPI im. Igoria Sikorskoho». 292 p. — https://ela.kpi.ua/ handle/123456789/35084. (Ukr.)

Sienkiewicz M., Janik H., Borzędowska-Labuda K., Kucińska-Lipka J. (2017). Environmentally friendly polymer-rubber composites obtained from waste tyres: A review. Journal of Cleaner Production, 147, pp. 560–571. DOI: http://dx.doi.org/10.1016/j.jclepro.2017.01.121

Mikulionok I.O. (2015). Classification of Processes and Equipment for Manufacture of Continuous Products from Thermoplastic Materials. Chemical and Petroleum Engineering, 51 (1–2), pp. 14–19. DOI: 10.1007/s10556-015-9990-6

Mikulionok I.O. (2013). Screw extruder mixing and dispersing units. Chemical and Petroleum Engineering, 49 (1–2), pp. 103–109. DOI: 10.1007/s10556-013-9711-y

Mikulyonok I.O. (2013). Equipment for preparing and continuous molding of thermoplastic composites. Chemical and Petroleum Engineering, 48 (11–12), pp. 658–661. DOI: 10.1007/s10556-013-9676-x

Kroll L., Hoyer S., Klaerner M. (2018). Production technology of cores for hybrid laminates containing rubber powder from scrap tyres. Procedia Manufacturing, 21, pp. 591–598. DOI: 10.1016/j.promfg.2018.02.160

Mikulenok I.O. (2014). Intensification of Fabrication of Extruded Polymeric Shapes. Chemical and Petroleum Engineering, 50 (7–8), pp. 483–488. DOI: 10.1007/s10556-014-9927-5

Drozdovskiy V.F. (1989). Sposoby proizvodstva regenerata. [Regenerate production methods]. Moscow: TsNIITEneftekhim, 88 p. (Seriya «Proizvodstvo shin»; Iss. 5). (Rus.)

Utilizatsiya i obezvrezhivaniye otkhodov (krome obezvrezhivaniya termicheskim sposobom (szhiganiye otkhodov). Informatsionno-tekhnicheskiy spravochnik po nailuchshim dostupnym tekhnologiyam ITS 15-2016. [Recycling and disposal of waste (except for thermal treatment (waste incineration). Information and technical guide to the best available technologies ITS 15-2016]. Moscow: Biuro NDT, 2016. 198 p. (Rus.)

Sokolov M.V., Nikolyukin M.V. (2011). Perspektivy primeneniya ultrazvuka pri proizvodstve devulkanizata. [Prospects for the use of ultrasound in the production of devulcanizate]. Vestnik TGTU, 17 (1), pp. 104–109. (Rus.)

Ghosh J., Hait S., Ghorai S., Mondal D., Wießner S., Das A., De D. (2020). Cradle-to-cradle approach to waste tyres and development of silica based green tyre composites. Resources, Conservation & Recycling, 154, Article 104629, 13 p. DOI: https://doi.org/10.1016/j.resconrec.2019.104629

Rekhaye A., Jeetah P. (2017). Assessing Energy Potential from Waste Tyres in Mauritius by Direct Combustion, Pyrolysis and Gasification. pp. 113–125. In: The Nexus: Energy, Environment and Climate Change. Series Green Energy and Technology. W.Leal Filho, D.Surroop (eds.). New York City: Springer International Publishing AG, 2018. 388 p. DOI: 10.1007/978-3-319-63612-2_7

Obezvrezhivanite otkhodov termicheskim sposobom (szhiganiye otkhodov). Informatsionno-tekhnicheskiy spravochnik po nailuchshim dostupnym tekhnologiyam ITS 9-2015. [Thermal disposal of waste (waste incineration). Information and technical guide on the best available technologies ITS 9-2015]. Moscow: Byuro NDT, 2015. 249 p. (Rus.)

Shinnaya promyshlennost: ekspress-informatsiya [Tire industry: express information]. Moscow: TsNIITEneftekhim, 1991, 10, 25 p. (Rus.)

Zang G., Jia J., Shi Y., Sharma T., Ratner A. (2019). Modeling and economic analysis of waste tire gasification in fluidized and fixed bed gasifiers. Waste Management, 89, pp. 201–211. doi: https://doi.org/10.1016/j.wasman.2019.03.070

Ongen A., Ozcan H.K., Elmaslar Ozbas E., Pangaliyev Y. (2019). Gasification of waste tires in a circulating fixed-bed reactor within the scope of waste to energy. Clean Technologies and Environmental Policy, 21, pp. 1281–1291. doi: 10.1007/s10098-019-01705-0

Naveed S., Malik A., Ramzan N., Akram M. (2009). A comparative study of gasification of food waste (FW), poultry waste (PW), municipal solid waste (MSW) and used tires (UT). The Nucleus, 46 (3), pp. 77–81. — http://www.thenucleuspak.org.pk/index.php/Nucleus/article/view/929/593 (Accessed May 02, 2021)

Mikáczó V., Zsemberi A., Siménfalvi Z., Palotás Á.B. (2017). Investigation of Tyre Recycling Possibilities with Cracking Process. pp. 155–169. In: Vehicle and Automotive Engineering / K.Jármai, B.Bolló (eds.). New York City: Springer International Publishing AG. 500 p. DOI: 10.1007/978-3-319-51189-4_16

Sathiskumar C., Karthikeyan S. (2019). Recycling of waste tires and its energy storage application of by-products — A review. Sustainable Materials and Technologies, 22, Article e00125, 6 p. — DOI: https://doi.org/10.1016/j.susmat.2019.e00125

Khudhair M.M., Omran R.J., Alameer H.A. (2020). Characterization study of liquid fuel produced from pyrolysis of waste tyres using different catalysts. AIP Conference Proceedings, 2290, Article 030009, 9 p. — DOI: https://doi.org/10.1063/5.0027869

Zahid M.U., Ali N., Khan W.A., Malik S.R. (2017). Effect of Operating Parameters on Bio-oil Yield from Pyrolysis of Waste Tyres in Lab Scale Fixed Bed Reactor. NFC IEFR Journal of Engineering and Scientific Research, 5 (1), 4 p. DOI: 10.24081/nijesr.2017.1.0002

Wang Z., Burra K. G., Zhang M., Li X., Policella M., Lei T., Gupta A.K. (2020). Co-pyrolysis of waste tire and pine bark for syngas and char production. Fuel, 274, Article 117878, 9 p. DOI: 10.1016/ j.fuel.2020.117878

Verma P., Zare A., Jafari M., Bodisco T.A., Rainey T., Ristovski Z.D., Brown R.J. (2018). Diesel engine performance and emissions with fuels derived from waste tyres. Scientific Reports, 8, Article 2457, 13 p. DOI: 10.1038/s41598-018-19330-0

Yaysun A.V., Konovalov P.N., Konovalov N.P. (2017). SVCh-piroliz iznodhennykh avtomobilnykh shin v prisutstvii gidroksida kaliya. [Microwave pyrolysis of worn-out car tires in the presence of potassium hydroxide]. Sovremennyye naukoyemkiye tekhnologii, No. 2, pp. 83–87. — http://www.top-technologies.ru/ru/article/view?id=36589 (Accessed April 24, 2021). (Rus.)

Ivanov S.R., Kruglova M.Yu., Platonova O.V., Oladov B.N. (1985). Sovremennoye sostoyzniye termicheskikh metodov pererabotki iznoshennykh shin i rezinosoderzhashchikh otkhodov. [The current state of thermal methods for the processing of used tires and rubber-containing waste]. Moscow : TsNIITEneftekhim, 49 p. (Rus.)

Mozafari A., Farshchi Tabrizi F., Farsi M., Seyed Mousavi S.A.H. (2017). Thermodynamic modeling and optimization of thermolysis and air gasification of waste tire. Journal of Analytical and Applied Pyrolysis, 126, pp. 415–422. — doi: http://dx.doi.org/doi:10.1016/j.jaap.2017.04.001

Mavukwana A., Stacey N., Fox J.A., Sempuga

B.C. (2021). Thermodynamic comparison of pyrolysis and gasification of waste tyres. Journal of Environmental Chemical Engineering, 9 (2), Article 105163. — doi: https://doi.org/10.1016/j.jece.2021.105163

Shiny iz biorazlagayemoy reziny mogut statrealnostyu. [Biodegradable rubber tires could be a reality]. — https://share.america.gov/ru/шины-из-биоразлагаемой-резины-могут-с/ (Accessed April 24, 2021). (Rus.)

Lao W.C., Toledo de R.A., Lu Q., Shim H. (2019). Degradation of scrap tyre by Bacillus sp. — Kinetic aspects of major environmental parameters and identification of potential growth substrates. International Biodeterioration & Biodegradation, 137, pp. 95–101. DOI: https://doi.org/10.1016/j.ibiod.2018.11.012

Dyrektyva Soveta Yevropeyskogo soyuza ot 26 aprelya 1999 g. O zakhoronenii otkhodov na poligonakh. [Council Directive 1999/31/ЕС of 26 April 1999 on the landfill of waste]. — https://zakon.rada.gov.ua/laws/show/994_925#Text (April 24, 2021). (Rus.)

Kasimov A.M., Semyenov V.T., Aleksandrov A.N., Kovalenko A.M. (2006). Tvyerdyye bytovyye otkhody. Problemy i resheniya. Tekhnologii, oborudovaniye. [Municipal solid waste. Problems and solutions. Technologies. Equipment]. Kharkov: KhNAGKh, 301 p. (Accessed April 24, 2021). (Rus.)

Ministerstvo rozvytku gromad ta terytorii Ukrainy: Stan sfery povodghennia z pobutovymi vadkhodamy v Ukraini za 2019 rik. [Ministry of De-velopment of Communities and Territories of Ukraine: The state of the sphere of household waste manage-ment in Ukraine in 2019]. — https://www.minregion.gov.ua/napryamki-diyalnosti/zhkh/terretory/stan-sfery-povodzhennya-z-pobutovymy-vi/ (Accessed April 24, 2021). (Ukr.)

Nanda S., Berruti F. (2021). Municipal solid waste management and landfilling technologies: A review. Environmental Chemistry Letters, 19, pp. 1433–1456. — doi: https://doi.org/10.1007/s10311-020-01100-y

Soo V.K., Peeters J., Compston P., Doolan M., Duflou J.R. (2017). Comparative Study of End-of-Life Vehicle Recycling in Australia and Belgium. Procedia CIRP, 61, pp. 269–274. doi: 10.1016/ j.procir.2016.11.222

Published
2021-09-20
How to Cite
Mikulionok, I. (2021). A STATE OF ART AND PROSPECTS OF USED PNEUMATIC TIRES MANAGEMENT (REVIEW). Energy Technologies & Resource Saving, (3), 63-83. https://doi.org/10.33070/etars.3.2021.06
Section
Raw material processing and resource saving

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