Разработка и исследование композиций, содержащих полимеры  и твердые углеродистые материалы

Е.И. Имaнбaев; Е.К. Онгарбаев; А.Б. Жамболова; Е. Тилеуберди; Е. Канжаркан; А.Р. Кенжегалиева; А.Н. Кыдырали; Д. Мукталы

doi:10.18321/cpc23(3)273-286

Authors

Y.I. Imanbayev Institute of Combustion Problems, Bogenbai Batyr st., 172, Almaty, Kazakhstan
Y.K. Ongarbayev Institute of Combustion Problems, Bogenbai Batyr st., 172, Almaty, Kazakhstan; Al-Farabi Kazakh National University, Al-Farabi ave., 71, Almaty, Kazakhstan
A.B. Zhambolova Institute of Combustion Problems, Bogenbai Batyr st., 172, Almaty, Kazakhstan
Y. Tileuberdi Institute of Combustion Problems, Bogenbai Batyr st., 172, Almaty, Kazakhstan
Y. Kanzhankan Abai Kazakh National Pedagogical University, Dostyk ave., 13, Almaty, Kazakhstan
A.R. Kenzhegaliyeva Institute of Combustion Problems, Bogenbai Batyr st., 172, Almaty, Kazakhstan
A.N. Kydyrali Al-Farabi Kazakh National University, Al-Farabi ave., 71, Almaty, Kazakhstan
D. Muktaly Institute of Combustion Problems, Bogenbai Batyr st., 172, Almaty, Kazakhstan

DOI:

https://doi.org/10.18321/cpc23(3)273-286

Keywords:

bitumen, modification, coke, mechanochemical processing, polymer waste, polymer-bitumen binders, modifier

Abstract

The use of household polymer waste in bitumen modification is one of the promising areas that allows providing the road surface with maximum resistance to fatigue failure, resistance to temperature changes in daily and seasonal cycles and a direction in solving environmental problems. In addition, using polymer waste can solve the problem of the increased cost of bitumen modified with polymers. In this research work, the compositions and physical-chemical characteristics of bitumen, polymer-bitumen binders and coal coke are studied. The detailed chemical composition of coal coke was studied using IR spectroscopy and thermogravimetric analysis. Addition of microdispersed coke during bitumen modification shows improvement of the characteristics of the obtained product similar to polymer-bitumen binders. Polymer-bitumen binder with addition of polymer waste and polymer modifier Elvaloy meets the requirements of ST RK 2534-2014 for BMP 50/70 in terms of its main indicators. During the process of bitumen modification with polymer waste, polymer particles physically react with high-molecular components (asphaltenes, resins and polyaromatic compounds), which affects the physical and mechanical properties of the bitumen binder: the softening temperature increases, the penetration and ductility values decreased. Addition of microdispersed granulated coke powders for modification of road bitumen meets the requirement of PBB 40 according to GOST R 52056-2003.

References

(1) A. Riekstins, V. Haritonovs, V. Straupe, et al. Comparative environmental and economic assessment of a road pavement containing multiple sustainable materials and technologies, Constr. Build. Mater. 432 (2024) 136522. Crossref

(2) A. V. Bazhenov, I. V. Kuzik. Use of coke as a bitumen modifier: Patent 2753763 RF, Bull. No. 24 (2021) 23.08.2021. URL (in Russian).

(3) A. V. Korotkov, O. N. Voytenko, D. V. Orlov, I. V. Ushakova, A. N. Nechaev, A. A. Mikhajlov, V. M. Kuznetsova. Structuring additive for asphalt concrete mixtures: Patent 2793038 RF. Bull. No. 10, 28.03.2023. URL (in Russian).

(4) A.D. Korneev, M.A. Goncharova, S.A. Andriyantseva, A.V. Komarichev. Optimization of construction and technical properties of asphalt concrete using metallurgical waste, Fundam. Res. 2 (2015) 1620–1625. Available at: URL (in Russian).

(5) V.M. Gotovtsev, A.G. Shatunov, A.N. Rumyantsev, V.D. Sukhov. Nanotechnologies in asphalt concrete production, Fundam. Res. 1 (2013) 191–195. Available at: URL (in Russian).

(6) V.M. Ufimtsev, F.L. Kapustin, V.A. Pyachev. Application of petroleum coke in the production of binders, AlitInform-Cement. Concrete. Dry Mixtures 3(2) (2008) 23–28. Available at: URL (in Russian).

(7) I.R. Khairutdinov, B.S. Zhirnov, I.M. Arpishkin. Aspects of using sulfur petroleum coke in cement production, Bashkir Chem. J. 19(4) (2012) 215–219. Available at: URL (in Russian).

(8) ODM 218.4.036-2017. Methodological recommendations for the preparation of asphalt concrete mixtures, their laying, and acceptance of completed works, based on the SUPERPAVE methodology, Federal Road Agency, Moscow, 2017. Available at: URL (in Russian).

(9) O.R. Parshukova, A.G. Egorov, A.A. Andreev, P.M. Tyukilina, R.V. Karpeko. Study of correlations of petroleum road bitumen properties using the SUPERPAVE methodology, Oil Refining and Petrochemistry 11 (2020) 9–16. Available at: URL (in Russian).

(10) GOST R 58400.10-2019. Public roads. Petroleum bituminous binders. Method for determining properties using a dynamic shear rheometer (DSR), Standartinform, Moscow, 2019. Available at: URL (in Russian).

(11) Y. Xue, Z. Ge, F. Li, et al. Modified asphalt properties by blending petroleum asphalt and coal tar pitch, Fuel 207 (2017) 64–70. Crossref

(12) H.H. Schobert, C. Song. Chemicals and materials from coal in the 21st century, Fuel 81 (2002) 15–32. Crossref

(13) A.S. Pull. Coal tar and paving products, Environ. Health Perspect. 114 (2006) 210–215. Crossref

(14) Y. Xue, J. Yang, Z. Liu, et al. Paving asphalt modifier from co-processing of FCC slurry with coal, Catal. Today 98 (2004) 333–338. Crossref

(15) M. Wu, J. Yang, Y. Zhang. Comparison study of modified asphalt by different coal liquefaction residues and different preparation methods, Fuel 100 (2012) 66–72. Crossref

(16) H. Chang, X. Li, L. Liu. Preparation process of coal tar pitch powder and its stability research, Sci. Technol. Energ. Mater. 74 (2013) 41–46. URL

(17) J. Alcaiz-Monge, D. Cazorla-Amoros, A. Linares-Solano. Characterization of coal tar pitches by thermal analysis, infrared spectroscopy and solvent fractionation, Fuel 80 (2001) 41–48. Crossref

(18) K.M. Sadeghi, M. Sadeghi, W.H. Wu, et al. Fractionation of various heavy oils and bitumen for characterization based on polarity, Fuel 68 (1989) 782–787. Crossref

(19) S.Q. Gu, Z.Q. Xu, Y.G. Ren, et al. Energy utilization of direct coal liquefaction residue via co-slurry with lignite: Slurryability, combustion characteristics, and their typical pollutant emissions, Fuel 326 (2022) 125037. Crossref

(20) Y.H. Song, S.M. Lei, J.C. Li, et al. In situ FT-IR analysis of coke formation mechanism during co-pyrolysis of low-rank coal and direct coal liquefaction residue, Renew. Energy 179 (2021) 2048–2062. Crossref

(21) R.M. Song, A.M. Sha, K. Shi, J.R. Li, et al. Polyphosphoric acid and plasticizer modified asphalt: Rheological properties and modification mechanism, Constr. Build. Mater. 309 (2021) 125158. Crossref

(22) Y.J. Wang, H.B. Zuo, K.K. Bai, et al. Preparation of hot-pressed coal briquette with the extract from direct coal liquefaction residue, J. Clean. Prod. 341 (2022) 130836. Crossref

(23) J. Jie, X.Q. Xin, X. Ying, et al. Research on performance of direct coal liquefaction residue modified asphalt mortar, J. Fuel Chem. Technol. 49 (2021) 1095–1101. Crossref

(24) J.L. Yang, Z.X. Wang, Z.Y. Liu, et al. Novel use of residue from direct coal liquefaction process, Energy Fuels 23 (2009) 4717–4722. Crossref

(25) J. Ji, H. Yao, X. Yang, et al. Performance analysis of direct coal liquefaction residue (DCLR) and Trinidad lake asphalt (TLA) for the purpose of modifying traditional asphalt, Arab. J. Sci. Eng. 41 (2016) 3983–3993. Crossref

(26) J. Ji, Z. Wang, P.F. Li, et al. A review on direct coal liquefaction residue applied in asphalt pavements, J. Clean. Prod. 395 (2023) 136273. Crossref

(27) K.P. Murugan, M. Balaji, S.S. Kar, et al. Nano fibrous carbon produced from chromium bearing tannery solid waste as the bitumen modifier, J. Environ. Manage. 270 (2020) 110882. Crossref

(28) H.J. Kadhim, A. Modarres, S. Al-Busaltan. Rheological and microstructural properties of nano-composite bitumen modified by nano-alumina and low-SBS content, Case Stud. Constr. Mater. 20 (2024) e03244. Crossref

(29) A.H. Zghair Chfata, H. Yaacob, N.H. Mohd Kamaruddin, et al. Laboratory evaluation of micro and nano eggshell powder on physical and rheological properties of bitumen, Green Technol. Sustain. 3 (2025) 100212. Crossref

(30) M. Arabani, M. Sadeghnejad, J. Haghanipour, et al. The influence of rice bran oil and nano-calcium oxide into bitumen as sustainable modifiers, Case Stud. Constr. Mater. 21 (2024) e03458. Crossref

(31) M.A.H. Al-Jumaili. Sustainability of asphalt paving materials containing different waste materials, IOP Conf. Ser.: Mater. Sci. Eng. 454 (2018) 012176. Crossref

(32) A. Modarres, H. Hamedi. Effect of waste plastic bottles on the stiffness and fatigue properties of modified asphalt mixes, Mater. Des. 61 (2014) 8–15. Crossref

(33) L. Cong, J. Peng, Z. Guo, et al. Evaluation of fatigue cracking in asphalt mixtures based on surface energy, J. Mater. Civ. Eng. 29 (2015) D4015003. Crossref

(34) T.B. Moghaddam, M. Soltani, M.R. Karim. Experimental characterization of rutting performance of Polyethylene Terephthalate modified asphalt mixtures under static and dynamic loads, Constr. Build. Mater. 65 (2014) 487–494. Crossref

(35) T.B. Moghaddam, M. Soltani, M.R. Karim. Evaluation of permanent deformation characteristics of unmodified and Polyethylene Terephthalate modified asphalt mixtures using dynamic creep test, Mater. Des. 53 (2014) 317–324. Crossref

(36) M. Jasso, J.S. Perez Jaimes, E.F. Tellez Vega. Mechanism and Development of Thermo-Rheological Properties of Asphalts Modified by Reactive Polymer Systems, Materials 16 (2023) 6631. Crossref

(37) D.A. Ayupov, L.I. Potapova, A.V. Murafa, V.Kh. Fakhrutdinova, Yu.N. Khakimullin, V.G. Khozin. Study of the features of interaction between bitumen and polymers, Izv. KazGASU 1(15) (2011) 140–146. Available at: URL (in Russian).

(38) G. Polacco, S. Filippi, F. Merusi, et al. A review of the fundamentals of polymer-modified asphalts: Asphalt/polymer interactions and principles of compatibility, Adv. Colloid Interface Sci. 224 (2015) 72–112. Crossref

(39) N.S. Akimbekov, I. Digel, M. Kozhahmetova, et al. Microbial Co-processing and Beneficiation of Low-rank Coals for Clean Fuel Production: A Review, Eng. Sci. 25 (2023) 942. Crossref