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Abstrakty
In recent years, the scale of use of recycled asphalt pavements for the production of hot mix asphalt (HMA) in Poland has been much smaller than in most other developed countries. Recently issued legal regulations and technical guidelines give hope for significant progres in this field. The article aims to investigate the parameters of HMA containing asphalt granulate (AG) in the context of using locally available materials and increasing the percentage of AG above the maximum amount recommended by current guidelines. It was found that the content of up to 40% AG used as an aggregate replacement does not significantly worsen the key parameters of HMA intended for the construction of an asphalt concrete subbase. The use of asphalt granulate may also result in a significant (up to approximately 50%) reduction in the consumption of road bitumen for the production of HMA
Rocznik
Tom
Strony
15--22
Opis fizyczny
Bibliogr. 26 poz., rys., tab.
Twórcy
autor
- Czestochowa University of Technology, Faculty of Civil Engineering (graudate), Poland
autor
- Czestochowa University of Technology, Faculty of Civil Engineering, Poland
Bibliografia
- 1. Abdel-Jaber, M., Al-shamayleh, R., Ibrahim, R., Alkhrissat, T. & Alqatamin, A. (2022) Mechanical properties evaluation of asphalt mixtures with variable contents of reclaimed asphalt pavement (RAP). Results in Engineering, 14, 100463.
- 2. Act of 14 December 2012 on waste. OJ 2013, item 21.
- 3. Andrew, B., Buyondo, K.A., Kasedde, H., Kirabira J.B., Olupot, P.W. & Yusuf, A.A. (2022) Investigation on the use of reclaimed asphalt pavement along with steel fibers in concrete. Case Studies in Construction Materials, 17, e01356.
- 4. Buss, A., Cascione, A. & Williams, R.C. (2014) Evaluation of warm mix asphalt containing recycled asphalt shingles. Construction and Building Materials, 61, 1-9.
- 5. Dębska, B., Krasoń, J. & Lichołaj, L. (2021) The evaluation of the possible utilization of waste glass in sustainable mortars. Construction of Optimized Energy Potential, 9(2), 7-15.
- 6. Harwat, A. & Respondek, Z. (2023) Assessment of the application of lumpy steel slag as an aggregate replacement in concrete. In: Ulewicz, R., Radek, N. & Pietraszek, J. (Eds.) Quality Production Improvement and System Safety. QPI 16-CZOTO 10, Materials Research Proceedings 34, 139-144.
- 7. Helbrych, P. (2021) Effect of dosing with propylene fibers on the mechanical properties of concretes. Construction of Optimized Energy Potential, 10(2), 39-44.
- 8. Jura, J. & Ulewicz, M. (2021) Assessment of the possibility of using fly ash from biomass combustion for concrete. Materials, 14(21), 6708.
- 9. Karthikeyan, K., Kothandaraman, S. & Sarang, G. (2023) Perspectives on the utilization of reclaimed asphalt pavement in concrete pavement construction: A critical review. Case Studies in Construction Materials, 19, e02242.
- 10. Kukiełka, J. (2013) Nawierzchnie asfaltowe dróg samorządowych. Politechnika Lubelska, Lublin.
- 11. Lis, T. & Nowacki, K. (2022) Pro-ecological possibilities of using metallurgical waste in the production of aggregates. Production Engineering Archives, 28(3), 252-256.
- 12. Ołdakowska, E. & Ołdakowski, J. (2021) Financial aspect of using the asphalt granulate in mixtures designed for road substructures. Ekonomia i Środowisko, 2(77), 81-94.
- 13. Pietrzak, A. & Ulewicz, M. (2023) Influence of post-consumer waste thermoplastic elastomers obtained from used car floor mats on concrete properties. Materials, 16(6), 2231.
- 14. PN-EN 12697-5 – Mieszanki mineralno-asfaltowe -- Metody badania mieszanek mineralno-asfaltowych na gorąco -- Część 5: Oznaczanie gęstości.
- 15. PN-EN 12697-6 – Mieszanki mineralno-asfaltowe -- Metody badania mieszanek mineralno-asfaltowych na gorąco -- Część 6: Oznaczanie gęstości objętościowej próbek mieszanki mineralno-asfaltowej.
- 16. PN-EN 12697-22 – Mieszanki mineralno-asfaltowe -- Metody badania mieszanek mineralno-asfaltowych na gorąco -- Część 22: Koleinowanie.
- 17. PN-EN 12697-12 – Mieszanki mineralno-asfaltowe -- Metody badania mieszanek mineralno-asfaltowych na gorąco -- Część 12: Określanie wrażliwości próbek asfaltowych na wodę.
- 18. Regulation of the Minister of Climate and Environment of 23 December 2021 on determining the detailed conditions for losing the waste status for reclaimed asphalt pavement. OJ 2021, item 2468.
- 19. Remixing przyszłością remontów dróg. Available online: https://edroga.pl/drogi-i-mosty/remixingprzyszloscia- remontow-drog-21052134 (accessed on 10 October 2023).
- 20. RID 9.2.1 Wytyczne pozyskania i oceny przydatności destruktu i granulatu asfaltowego do recyklingu na gorąco w otaczarkach (2019). GDDKiA, Warszawa.
- 21. Ruttmar, I. & Koźlarek, P. (2018) Możliwości ponownego wykorzystania granulatu asfaltowego z destruktu w oparciu o polskie i niemieckie doświadczenia. Available online: https://kongresdrogowy.pl/wp-content/uploads/files-pdf/LOD_IRuttmar.pdf (accessed on 10 October 2023).
- 22. Tomov, M. & Velkoska, C. (2022) Contribution of the quality costs to sustainable development. Production Engineering Archives, 28(2), 164-171.
- 23. WT-2 Nawierzchnie asfaltowe na drogach krajowych. Część I: Mieszanki mineralno-asfaltowe. Wymagania techniczne (2014). GDDKiA, Warszawa.
- 24. Xiao, F., Xu, L., Zhao, Z. & Hou, X. (2023) Recent applications and developments of reclaimed asphalt pavement in China, 2010-2021. Sustainable Materials and Technologies, 37, e00697.
- 25. Yu, X., Xie, Y., Yao, H. & Wang, S. (2023) Excellent low temperature performance for modified asphalt by finely dispersed sidewall tire rubber. Construction and Building Materials, 392, 131939.
- 26. Zieliński, P. (2022) Testing of asphalt mixtures containing an addition of reclaimed asphalt shingles. Roads and Bridges - Drogi i Mosty, 21, 277-292.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-d12a953d-7304-4ff6-a52c-4576426ecad6