Satatov, Saratov, Russian Federation
Saratov, Saratov, Russian Federation
Saratov, Saratov, Russian Federation
Moscow, Moscow, Russian Federation
Voronezh, Voronezh, Russian Federation
UDK 62-16/-17 Характеристики машин по способу использования рабочего тела
The paper concerns with an assessment of the effect of basalt fiber cutting density and length on the risk of thread entangling. The average lengths of basalt fiber filaments do not exceed critical values. The histogram of the basalt fiber length distribution corresponds to the normal distribution with an excellent rating. The research ascertained the maximum permissible imperfection of the distribution of lengths of fluffed basalt filaments. Hence, expected risk of thread entangling is lower than permissible one. Therefore, it is acceptable to implement dispersed reinforcement of this fiber from basalt fiber at the required level of reliability.
basalt fiber, asphalt concrete, reinforcement, risk, density, thread length, distribution law
1. Yankovskiy, L.V., Kochetkov, A.V. & Kokodeeva, N.E. (2019) Technical regulation of the macro-roughness of road surfaces of automobile and logging roads. Perm: Izd-vo Perm. nats. issled. politekhn. un-ta (in Russian).
2. Andronov, S.Yu., Ivanov, A.F. & Kochetkov, A.V. (2020) Highway repair with the use of fiber-containing asphalt concrete mixtures with dispersed binder, Stroitel'nye materialy, (4-5), pp. 62-67 (in Russian).
3. Andronov, S.Yu., Ivanov, A.F. & Kochetkov, A.V. (2020) Technology of production and application of dispersed reinforced asphalt concrete mixtures with basalt fiber, Stroitel'nye materialy, (3), pp. 70-75 (in Russian).
4. Andronov, S.Yu., Alferov, V.I. & Kochetkov, A.V. (2020) Improving the methods of introducing fiber fibers into hot and cold asphalt concrete mixtures, Vestnik evrazijskoj nauki, 12(2), p. 2 (in Russian).
5. Andronov, S.Yu., Artemenko, A.A., Kokodeeva, N.E. et al. (2017) An attachment for processing fiber before introducing it into a road-building reinforced mixture. Utility model patent RU 170486 U1 (in Russian).
6. Andronov, S.Yu., Artemenko, A.A., Arzamascev S.V. et al. (2017) An attachment for processing fiber before introducing it into a road-building reinforced mixture. Utility model patent RU 171296 U1 (in Russian).
7. Kochetkov, A.V., Andronov, S.Yu., Ivanov, A.F., Kokodeeva, N.E., Kozin, A.S. & Pachina, O.V. (2019) Bitumen suspension. Saratov: Sarat. gos. tekhn. un-t (in Russian).
8. Akulova, N.E., Shchegoleva, N.V. & Stolyarov, V.V. (2020) TST-RISK. Certificate of registration of the computer program RU 2020612667 (in Russian).
9. Andronov, S., Kokodeeva, N., Vasiliev, Y., Kotlyarsky, E. & Kochetkov, A. (2021) Impact study of basalt and polyacrylonitrile fibercon performance characteristics of asphalt concrete, Advances in Intelligent Systems and Computing, 1258, pp. 473-485.
10. Di, Yu, Wensheng, Wang, Yongchun, Cheng & Yafeng, Gong (2016) Laboratory investigation on the properties of asphalt mixtures modified with double-adding admixtures and sensitivity analysis, Journal of Traffic and Transportation Engineering (English Edition). DOI:https://doi.org/10.1016/j.jtte.2016.09.002.
11. Yongchun, Cheng, Di, Yu, Guojin, Tan & Chunfeng, Zhu (2018) Low-Temperature Performance and Damage Constitutive Model of Eco-Friendly Basalt Fiber–Diatomite-Modified Asphalt Mixture under Freeze–Thaw Cycles, Materials, 11(11), 2148. DOI:https://doi.org/10.3390/ma11112148.
12. Clara, Celauro, Filippo, Praticò (2018) Asphalt mixtures modified with basalt fibres for surface courses, Construction and Building Materials, 170, pp. 245-253. DOI:https://doi.org/10.1016/j.conbuildmat.2018.03.058
13. Yafeng, Gong, Haipeng, Bi, Chunyu, Liang & Shurong, Wang (2018) Microstructure Analysis of Modified Asphalt Mixtures under Freeze-Thaw Cycles Based on CT Scanning Technology, Applied Sciences, 8(11), 2191, DOI:https://doi.org/10.3390/app8112191.
14. Xiao, Qin, Aiqin, Shen, Yinchuan, Guo & Zhennan, Li (2018) Characterization of asphalt mastics reinforced with basalt fibers, Construction and Building Materials, 159, pp. 508-516. DOI:https://doi.org/10.1016/j.conbuildmat. 2017.11.012.
15. Yafeng, Gong, Haipeng, Bi, Zhenhong, Tian & Guojin, Tan (2018) Pavement Performance Investigation of Nano-TiO2/CaCO3 and Basalt Fiber Composite Modified Asphalt Mixture under Freeze‒Thaw Cycles, Applied Sciences, 8(12), p. 2581. DOI:https://doi.org/10.3390/app8122581.
16. Andronov, S.Yu., Stolyarov, V.V., Valiev, Sh.N. & Kochetkov, A.V. (2023) The length of fiber strands for reinforcing asphalt concrete mix, Smart composites in construction, 4(3), pp. 55-65 [online]. Available at: https://drive.google.com/file/d/14QOFySop_RkqhnBY5BZ-gPqnCbgBJM8a/view (in Russian).
17. Pearson's table | Matematicus [online]. Available at: https://www.matematicus.ru/teoriya-veroyatnosti/tablitsy/tablitsa-pirsona (accessed: February 19, 2024) (in Russian).
18. Khusnutdinov, R. S. (2019) Mathematical statistics. Moscow: Infra-M (in Russian).
