Abstract: The paper aimed at assessing the feasibility of using natural zeolites as a mineral filler substitute for asphalt mixtures produced at around 120 ◦C temperatures with a water foamed binder
and compacted at 100 ◦C. The tests utilized the AC 16 asphalt concrete mixture intended for the binder and base course with the mineral filler fraction amounting to 4% by wt. comprising limestone dust and zeolites (when added). A reference hot mix and warm mix with foamed bitumen were compared to two mixes with zeolites, with one containing 0.4% of a water-modified (20% moisture content) zeolite and the second containing 1.0% of natural air-dried zeolite. The investigations included: assessment of campactability using a gyratory compactor, air void content, indirect tensile strength before and after conditioning with one freeze-thaw cycle, and the resulting resistance to moisture and frost damage. The mixtures with zeolites exhibited decreased compactability when compared to reference mixes, which the Marshall samples confirmed. The mechanical properties have also deteriorated in zeolite-bearing mixtures, which was partially accounted to the decreased compaction level. It was concluded that the temperature of the mixture production was too low for the zeolite water to significantly improve the compactablity of the asphalt mixture and its mechanical parameters.
B I B L I O G R A F I A1. Jenkins, K.J. Mix Design Considerations for Cold and Half-Warm Bituminous Mixes with Emphasis on Foamed Bitumen. Ph.D. Thesis, University of Stellenbosch, Stellenbosch, South Africa, 2000.
2. Jenkins, K.J. de Groot, J.L.A. Van de Ven, M.F.C. Molenaar, A.A.A. Half-warm foamed bitumen treatment, a new process. In Proceedings of the 7th Conference on Asphalt Pavements for Southern Africa, Livingstone, Zimbabwe, 30 Aug – 2 Sep 1999.
3. Jenkins, K.J. Molenaar, A.A. de Groot, J.L.A. Van de Ven, M.F.C. Foamed Asphalt Produced Using Warmed Aggregates. J. Assoc. Asph. Paving Technol. 2002, 71, 444–478.
4. Chomicz-Kowalska, A. Gardziejczyk, W. Iwański, M.M. Moisture resistance and compactibility of asphalt concrete producedin half-warm mix asphalt technology with foamed bitumen. Constr. Build. Mater. 2016, 108–118, doi:10.1016/j.conbuildmat.2016.09.004.
5. Chomicz-Kowalska, A. Gardziejczyk, W. Iwański, M.M. Analysis of IT-CY stiffness modulus of foamed bitumen asphalt concrete compacted at 95 °C. Procedia Eng. 2017, 172, 550–559, doi:10.1016/j.proeng.2017.02.065.
6. Woszuk, A. Panek, R. Madej, J. Zofka, A. Franus, W. Mesoporous silica material MCM-41: Novel additive for warm mix asphalts. Constr. Build. Mater. 2018, 183, 270–274, doi:10.1016/j.conbuildmat.2018.06.177.
7. Iwański, M.M. Chomicz-Kowalska, A. Maciejewski, K. Impact of Additives on the Foamability of a Road Paving Bitumen. In IOP Conference Series: Materials Science and Engineering 603 IOP Publishing: Bristol, UK, 2019, doi:10.1088/1757-899X/603/4/042040.
8. Prowell, B. Hurley, G. Frank, B. Warm-Mix Asphalt: Best Practices, 3rd ed. National Asphalt Pavement Association: Greenbelt, MD, USA, 2012.
9. Iwański, M. Chomicz-Kowalska, A. Maciejewski, K. Application of synthetic wax for improvement of foamed bitumen parameters. Constr. Build. Mater. 2015, 83, 62–69, doi:10.1016/j.conbuildmat.2015.02.060.
10. Iwanski, M.M. Chomicz-Kowalska, A. Maciejewski, K. Effect of Surface Active Agent (SAA) on 50/70 Bitumen Foaming Characteristics. Materials 2019, 12, 3514, doi:10.3390/ma12213514.
11. Larsen, O.R. Moen, O. Robertus, C. Koenders, B.G. WAM foam asphalt production at lower operating temperatures as an environmental friendly alternative to HMA. In Proceedings of the 3rd Eurasphalt & Eurobitume Congress, Vienna, Austria, 12–14 May 2004 p. 137.
12. Auerbach, S.M. Carrada, K.A. Dutta, P.K. Handbook of Zeolite Science and Technology Marcel Dekker, Inc.: New York, NY, USA, 2003.
13. Ciciszwili, G.W. Andronikaszwili, T.G. Zeolity Naturalne [Natural Zeolites] Wydawnictwo Naukowo-Techniczne: Warsaw, Poland, 1990.
14. Kasperkowiak, M. Materiały Mikro-i Mezoporowate Jako Napełniacze Aktywne. [Micro- and Mesoporous Materials as Active Fillers]. Ph.D. Thesis, Poznań, Poznan University of Technology, Poland, 2014.
15. Lippmaa, E. Mägi, M. Samoson, A. Tarmak, M. Engelhardt, G. Investigation of the Structure of Zeolites by Solid-State High-Resolution Silicon-29 NMR Spectroscopy. J. Am. Chem. Soc. 1981, 103, 4992–4996, doi:10.1021/ja00407a002.
16. Sassani, A. A Multi-Scale Approach to Characterization of Volcanic Natural Pozzolans. Master’s Thesis, Middle East Technical University, Ankara, Turkey, 2014.
17. Sassani, A. Turanli, L. Emwas, A.H. Meral, C. Mechanical performance, durability and aluminosilicate chain structure of high volume zeolitic natural pozzolan-portland cement based systems. In Proceedings of the ZEOLITE 2014—9th International Conference on the Occurrence, Properties, and Utilization of Natural Zeolites, Belgrade, Serbia, 8–13 June 2014 Institute for Technology of Nuclear and Other Mineral Raw Materials: Belgrade, Serbia, 2014.
18. Feng, N. Peng, G. Applications of natural zeolite to construction and building materials in China. Constr. Build. Mater. 2005, 579–584, doi:10.1016/j.conbuildmat.2005.01.013.
19. Uzal, B. Turanli, L. Blended cements containing high volume of natural zeolites: Properties, hydration and paste microstructure. Cem. Concr. Compos. 2012, 34, 101–109.
20. Wdowin, M. Wiatros-Motyka, M. Panek, R. Stevens Lee, A. Franus, W. Snape, C.E. Experimental study of mercury removal from exhaust gases. Fuel 2014, 128, 451–457, doi:10.1016/j.fuel.2014.03.041.
21. Woszuk, A. Franus, W. Properties of the Warm Mix Asphalt involving clinoptilolite and Na-P1 zeolite additive. Constr. Build. Mater. 2016, 114, 556–563, doi:10.1016/j.conbuildmat.2016.03.188.
22. Vogt, E.T.C. Whiting, G.T. Chowdhury, D.T. Weckhuysen, B.M. Chapter Two—Zeolites and Zeotypes for Oil and Gas Conversion. In Advances in Catalysis Elsevier: Amsterdam, The Netherlands, 2015 Volume 58, pp. 143–314, doi:10.1016/bs.acat.2015.10.001.
23. Yusupov, T.S. Shumskaya, L.G. Kirillova, Y.A. State and perspectives of natural zeolite beneficiation. J. Min. Sci. 2000, 36, 299–304.
24. Sarbak, Z. Nieorganiczne Materiały Nanoporowate [Inorganic Nanoporous Materials] Wydawnistwo UAM: Poznań, Poland, 2009.
25. Barthel, W. Marchand, J.-P. Devivere, M. Warm asphalt mixes by adding a synthetic Zeolite. In Proceedings of the 3rd Eurasphalt & Eurobitume Congress, Vienna, Austria, 12–14 May 2004.
26. Lai, B. Barros, C. Yin, H. Investigation of rheological behaviour of asphalt binder modified by the Advera additive. In Proceedings of the Poro-Mechanics IV: Fourth Biot Conference on Poromechanics, New York, NY, USA, 8–10 June 2009.
27. Woszuk, A. Wpływ dodatku zeolitów na obniżenie temperatury produkcji i zagęszczania mieszanek mineralno-asfaltowych. [Influence of Zeolite Addition on the Decrease in Production and Compaction Temperatures of Bituminous Mixtures]. Ph.D. Thesis, Lublin, Lublin University of Technology, Poland, 2016.
28. Technical recommendation IBDiM No. RT/2009-03-0012/1. In Adhesion Promoters Wetfix BE and Wetfix AP17 for Use in Traffic Engineering Road and Bridge Research Institute: Warsaw, Poland, 2014.
29. WETFIX BE. Thermally Stable Liquid Adhesion Promoter for Asphalt Binders Minova Ekochem, S.A.: Siemianowice Śląskie, Poland, 2010.
30. EN 1426:2015-08 Bitumen and Bituminous Binders—Determination of Needle Penetration Polish Committee for Standardization: Warsaw, Poland, 2015.
31. EN 1427:2015-08 Bitumen and Bituminous Binders—Determination of Softening Point—Ring and Ball Method Polish Committee for Standardization: Warsaw, Poland, 2015..
32. EN 12593:2015-08 Bitumen and Bituminous Binders—Determination of the Fraass Breaking Point Polish Committee for Standardization: Warsaw, Poland, 2015.
33. EN 12591:2009 Bitumen and Bituminous Binders—Specifications for Paving Grade Bitumens Polish Committee for Standardization: Warsaw, Poland, 2009.
34. EN 14023:2010 Bitumen and Bituminous Binders—Specification Framework for Polymer Modified Bitumens Polish Committee for Standardization: Warsaw, Poland, 2010.
35. Muthen, K.M. Foamed Asphalt Mixes. Mix Design Procedure. Contract Report CR 98/077 SABITA Ltd. & CSIR Transportek (Council for Scientific and Industrial Research Transportek): Pretoria, South Africa, 1999.
36. Technical Guideline TG2, Bitumen Stabilised Materials, A Guideline for the Design and Construction of Bitumen Emulsion and Foamed Bitumen Stabilised Materials, 2nd ed. Asphalt Academy: Pretoria, South Africa, 2009.
37. Asphalt Academy. The Design and Use of Foamed Bitumen Treated Materials. Interim Technical Guideline (TG2) Asphalt Academy: Pretoria, South Africa, 2002.
38. Wirtgen Cold Recycling Technology. Manual, 1st ed. Wirtgen GmbH: Windhagen, Germany, 2012.
39. Wirtgen Group. Podręcznik Recyklingu na Zimno [Cold Recycling Technology Manual], 2nd ed. Wirtgen GmbH: Windhagen, Germany, 2004.
40. Chomicz-Kowalska, A. Laboratory testing of low temperature asphalt concrete produced in foamed bitumen technology with fiber reinforcement. Bull. Pol. Acad. Sci. Tech. Sci. 2017, 65, 779 790, doi:10.1515/bpasts-2017-0086.
41. Chomicz-Kowalska, A. Mrugała, J. Maciejewski, K. Evaluation of foaming performance of bitumens modified with the addition of surface active agent. In IOP Conference Series: Materials Science and Engineering IOP Publishing: Bristol, UK, 2017 Volume 245, pp. 1‒10, doi:10.1088/1757-899X/245/3/032086.
42. EN 12594:2014-12 Bitumen and Bituminous Binders—Preparation of Test Samples.
43. EN 13043:2013 Aggregates for Bituminous Mixtures and Surface Treatments for Roads, Airfields and Other Trafficked Areas.
44. WT-2 2014—Part II. Asphalt Mixes. Technical Requirements. Appendix to Ordinance No. 47 of the General Director of National Roads and Highways. Available online: www.gddkia.gov.pl (accessed on 18 September 2019).
45. Iwański, M. Chomicz-Kowalska, A. Application of the foamed bitumen and bitumen emulsion to the road base mixes in the deep cold recycling technology. Balt. J. Road Bridge Eng. 2016, 11, 291–301, doi:10.3846/bjrbe.2016.34.
46. Iwański, M.M. Synergia Wapna Hydratyzowanego i Asfaltu Spienionego w Zapewnieniu Trwałości Eksploatacyjnej Betonu Asfaltowego w Technologii na Półciepło [Synergic Effects of Utilization of Hydrated Lime and Foamed Bitumen in Providing Service Durability of Half-Warm Mix Asphalt Concrete]. Ph.D. Thesis, Faculty of Civil Engineering and Architecture, Kielce University of Technology: Kielce, Poland, 2019.
47. EN 12697-5:2010 Bituminous Mixtures. Test Methods. Determination of the Maximum Density Polish Committee for Standardization: Warsaw, Poland, 2010.
48. EN 12697-6:2012 Bituminous Mixtures. Test Methods for Hot Mix Asphalt. Determination of Bulk Density of Bituminous Specimens Polish Committee for Standardization: Warsaw, Poland, 2012.
49. EN 12697-8:2005 Bituminous Mixtures. Test Methods. Determination of Void Characteristics of Bituminous Specimens Polish Committee for Standardization: Warsaw, Poland, 2005.
50. EN 12697-12:2008 Bituminous Mixtures. Test Methods. Determination of the Water Sensitivity of Bituminous Specimens Polish Committee for Standardization: Warsaw, Poland, 2008.
51. EN 12697-31:2008 Bituminous Mixtures. Test Methods. Specimen Preparation by Gyratory Compactor Polish Committee for Standardization: Warsaw, Poland, 2008.
52. WT-1 2014. Kruszywa do Mieszanek Mineralno-Asfaltowych i Powierzchniowych Utrwaleń na Drogach Krajowych. Wymagania Techniczne [Aggregates for Asphalt Mixes and Surface Dressings on National Highways. Technical Requirements]. 2014. Available online: www.gddkia.gov.pl (accessed on 18 September 2019).
53. EN 933-10:2009 Tests for Geometrical Properties of Aggregates. Assessment of Fines. Grading of Filler Aggregates (Air Jet Sieving) Polish Committee for Standardization: Warsaw, Poland, 2009.
54. EN 933-1:2012 Tests for Geometrical Properties of Aggregates. Determination of Particle Size Distribution. Sieving Method Polish Committee for Standardization: Warsaw, Poland, 2012.
55. Iwański, M. Chomicz-Kowalska, A Stępień, J. Maciejewski, K. Ramiączek, P. Iwański, M. M. Zalecenia Dotyczące Projektowania, Wytwarzania i Wbudowywania Mieszanek Mineralno Asfaltowych z Asfaltem Spienionym o Obniżonych Temperaturach Technologicznych [Technical Recommendations for Design, Production and Paving of Asphalt Mixes with Foamed Bitumen Characterized by Lowered Processing Temperatures]. RID-I/6 Report Recommendations, NCBiR, GDDKiA Kielce University of Technology: Kielce, Poland, 2018.
56. Radziszewski, P. Piłat, J. Król, K. Kowalski, K. Sarnowski, M.Ł. Weryfikacja Wymagań i Metody Oceny Właściwości Lepkosprężystych Krajowych Asfaltów i Asfaltów modyFikowanych [Verification of Requirements and Methods for assessment of Viscoelastic Properties of Domestic Bitumens and Polymer Modified Bitumens] Politechnika Warszawska: Warsaw, Poland, 2011.
57. Chomicz-Kowalska, A. Statistical methods for evaluating associations between selected foamed bitumen parameters. In Proceedings of the 6th International Conference on Bituminous Mixtures and Pavements--ICONFBMP 2015, Thessaloniki, Greece, 10–12 June 2015 Chapter I: Bituminous binders, Unbound materials, pp. 3–12.
58. Newcomb, D.E. Arambula, E. Yin, F. Zhang, J. Bhasin, A. Li, W. Zelalem, A. Properties of Foamed Asphalt for Warm Mix Asphalt Applications. NCHRP Report 807. TRB AASHTO: Washington, DC, USA, 2015. 
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