International Journal of Academic and Applied Research (IJAAR) ISSN: 2000-005X Vol. 2 Issue 3, March – 2018, Pages: 5-8 http://www.ijeais.org/ijaar 5 Dynamic Mechanical Properties of Bitumen Composites: Part II Mahmoud Abdel-Halim Abdel-Goad Chemical Engineering Dept., Faculty of Engineering, Minia University, Egypt E-mail:m.abdelhalim@mu.edu.eg Abstract: Waste polyethylene (PE) bags were reused in the modification of commercially available bitumen. The bitumen/PE blend was prepared by mixing homogenously commercial bitumen with waste PE in the molten state. The samples of bitumen blend and bitumen base were rheologically analyzied. The rheological properties such as complex modulus, shear compliance, torque and complex viscosity of bitumen and bitumen blend were studied using an ARESRheometer (Rheometric Scientific, Co.) in the dynamic mode, plate-plate geometry with diameter 8 mm. The measurements were performed over a wide range of temperatures ranged from-10°C to 60°C and frequencies from 100 to 0.1 radians per second. The results evidence that the shear compliance and torque are improved by the incorporation of the waste PE into bitumen. Keywords: bitumen; rheology, waste plastics. 1. INTRODUCTION Bitumen is the black adhesive that binds flexible pavements on roads and airfields together. Bitumen is also used in other areas of application, such as waterproofing, flooring and joint materials. Almost all bitumen originates from crude oil and is the residue of a refining process. It is well-known that bitumen is a very complex and temperature dependent material consisting of hydrocarbon molecules. Naphtenic-base crude oils often give a large yield of bitumen that may be of good quality, while paraffinic crude oils may give bitumen of good quality or yield bitumen not suitable for road construction [1]. Nowadays a very large majority of the roads are constructed using a mixture of bitumen (5 wt %) and mineral aggregates. Notwithstanding this low bitumen content, the performance of the road pavement depends to a large extent on the properties of bitumen itself, since it constitutes the only deformable component. The correlation between the complex colloidal structure of bitumen and its viscoelastic response is therefore a subject of scientific and technical interest [2 -7]. Polymer additives are well-known to improve the rheological properties of bitumen The polymer addition allows an increase in the resistance of the binder to permanent deformation at high temperature.Besides, the fracture properties including critical stress intensity factor (K1C) at low temperature of polymer modified bitumens (PmB's) were shown to be higher than those of the bitumen base.To determine the crack propagation mechanism controlling fracture properties, previous studies have focused on establishing the relationship between the fracture properties and the morphology of polymer modified bitumen [8]. The addition of synthetic polymers to enhance service properties over a wide range of temperatures in road paving applications was considered a long time ago and nowadays has become a real alternative. As has been pointed out in relevant papers about bitumen and polymer/ bitumen blends[9 -18 ] understanding the interactions of asphaltene and maltene (main components of bitumen) with the polymer, is a crucial point to gain insight into the routes to improve the capacities of these systems. In recent years, the volume of municipal plastic waste (MPW) has increased greatly, and this has resulted in a critical problem for modern society and future generations. Polyolefins, poly(ethylene terephthalate), Polyvinylchloride (PVC), polystyrene (PS), and high-impact polystyrene (HIPS) are among the most common components of plastic waste because they are among the most frequently used commercial plastics in our daily lives and in industry.Recycling mixed plastic residues in the form of blends is attractive from academic and industrial points of view because of the improvements in the impact strength , dimensional stability, stress cracking, and processability with respect to virgin blends[19]. In the present study, waste plastics are used as a filler for making bituminous roof mastic up to a level of 20 wt %. The viscoelasticity of a bitumen modified with waste 9wt% PE is analysed and compared to bitumen base. 2. EXPERIMENTS PART Materials and preparation Waste plastics were collected from the garbage, sorted and shredded into coarse particles. The waste plastics and commercial bitumen were weighted and heated individually in an oven until melt. Molten waste plastic was poured into the molten bitumen and stirred vigorously to give a homogenous sample. The hot mixtures were then cast into a ring stamp with 25 mm diameter and 2 mm thickness for rheology testing. Measurements Solid-state dynamic viscoelastic measurements of all the pure bitumen and bitumen blends samples were accomplished in a Solid state institute, Research center Juelich, Germany. In this study we used an ARESrheometer (Advanced Rheology Expanded System, Rheometric Scientific Co.,) in the dynamic mode, under International Journal of Academic and Applied Research (IJAAR) ISSN: 2000-005X Vol. 2 Issue 3, March – 2018, Pages: 5-8 http://www.ijeais.org/ijaar 6 nitrogen atmosphere, plate-plate geometry with 25 mm in diameter to determine the rheological characteristics of the neat bitumen and bitumen blends. The measurements were performed over a wide range of temperatures ranged from 25°C to 160°C and frequencies from 100 to 0.1 radians per second. A sample ( about 1.0 g) was placed in the lower plate then the upper parallel plate was lowered for a tight contact with the sample. All the samples were held at a constant temperature of 50°C for 10 min, cooled to 25°C and measured at temperatures (25, 40, 60, 80, 100, 110, 120, 130°C, 145°C and 160°C). The applied strain were 2%. 3. RESULTS AND DISCUSSIONS In this section the master curves at 25°C of the storage (J') and loss compliance (J'') versus  are presented in Figures 3 and 4, respectively. J'() is a measure of the energy stored and recovered per deformation cycle, therefore is called the storage compliance. And J''() is a measure of the energy dissipated as heat per cycle of the sinusoidal deformation, for that is called the loss compliance. Figures 1-2 show the dynamic shear compliances moduli for bitumen blends compared to pure bitumen. These Figures show clearly two regions reflect the behavior of the material under the measured temperatures as a function of. As shown in Figures 1-2 the incorporation of the waste PE into bitumen affect on the J'() and J''() moduli. Since these moduli are enhanced for the bitumen blends. This is clear at  ~ 5.210 3 radians/s where the value of J' changed from 1.510 -7 for neat bitumen to 1.010 -7 Pa -1 in the case of bitumen/PE blend. But at low frequencies the effect is more noticeable. since at  ~ 5.910-2 radians/s, the values of J' become 4.010 -5 and 1.310 -6 Pa -1 for pure bitumen, and bitumen blend, respectively. The same effect is observed also for J'' moduli in Figure 2. In this Figure at  ~ 91 radians/s the values of J'' are 4.310 -7 and 1.910 -8 Pa -1 for neat bitumen, bitumen-PE, respectively. This because of the matrix formation between the PE chains and bitumen which leads to increase the strength and stiffness. This increase in the stiffness and strength by the introduction of the waste PE to bitumen is confirmed also in the shear creep stress, J(t) in Figure 3. This Figure show J(t) as a function of time for pure bitumen and bitumen blends. As shown in Figure 3 J(t) increases with time and the difference between the values of J(t) in the case of neat bitumen and bitumen blends is higher at long times than at short times. Since at t ~ 200 seconds, the values of J(t) are, 1.110 -3 and 1.410 -5 Pa -1 for neat bitumen and bitumen-PE, respectively. This indicates the improvement of the stability of the bitumen for a long time by the addition of the waste PE due to network of bitumenPE. The torque in NM as a function of frequency for neat bitumen and bitumen blends are logarithmically plotted at 100°C in Figure 4. The torque decreases with decreasing the shear rates as shown in Figure 7.This Figure evidences also that the addition of waste plastics to bitumen enhances the torque. Since the torque increases from 5.010 -4 to 1.310 -3 , 2.710 -2 , 3.210 -1 , 4.310 0 and 5.710 1 NM by the addition of 3, 7, 9,13 and 20 % PET , respectively. This because the formation of the bitumen-plastic matrix which leads to increase stiffness of the bitumen blends. 4. CONCLUSION Waste PE bags were used as a modifier in making improved bitumen. The blend compared to bitumen base was subjected to evaluate their response against temperature and frequency sweeps. By using an ARESRheometer (Rheometric Scientific, Co.) in the dynamic mode and parallel plate geometry with diameter 8 mm. The measurements were performed over a wide range of temperatures ranged from – 10 to 60°C and frequencies from 100 to 0.1 radians per second. It was found that shear compliance and torque are enhanced by the incorporation of waste 9wt%PE. 5. ACKNOWLEDGMENTS The financial support by the International Bureau in Germany, helpful discussions of Dr. W.Pyckhout and Dr.S. Khale at FZJ, Germany are greatly acknowledged. REFERENCES [1] Y.Edwards, P.Redelius,Energy & Fuels, V17, P.511-520, 2003. [2] O. Gonzalez, J. J. Pena, M. E. Munoz, A. Santamaria, A. Perez-Lepe, F. Martinez-Boza, and C. Gallegos, V16, P. 1256 –1263, Energy Fuels, 2002. [3] Y.Khakimullin, A.Murafa, Z. Sungatova, E.Nagumanova, V.Khozin, V.36, P. 423-428, 2000. [4] A. Pérez-Lepe, F. J. Martínez-Boza, C. Gallegos, O. González, M. E. Muñoz and A. Santamaría, Fuel, V 82, P. 1339-1348, 2003. [5] P. R. Herrington, Y.Wu and M. C. Forbes, Fuel, V 78, P. 101-110 , 1999. [6] A. Chaala, C.Roy and A. Ait-Kadi, Fuel, V 75, P. 15751583, 1996. [7] L.Champion-Lapalu, A.Wilson, G.Fuchs, D. Martin, J.P. Planche, Energy & Fuels, V16, P.143-147, 2002. [8] A. H. Fawcett, T. McNally, Macromolecular Materials and Engineering, V286, P.126-137, 2001. [9] X. Lu and U. Isacsson, Fuel, V76, P. 1353-1359, 1997. [10] A. H. Fawcett, T. McNally, G. M. McNally, F. Andrews and J. Clarke, Polymer, V 40, P. 6337-6349, 1999. [11] Y. Ryabikin, V.Zashkvara , PETROLEUM CHEMISTRY,V43 P.286-288, 2003 [12] A.Kishita, S. Takahashi, H.Kamimura, M.Miki, T.Moriya, H.Enomoto, JOURNAL OF THE JAPAN PETROLEUM INSTITUTE V46, P.215-221, 2003. [13] J.Jehlicka, O.Urban, J.Pokorny, SPECTROCHIMICA ACTA PART A-MOLECULAR AND International Journal of Academic and Applied Research (IJAAR) ISSN: 2000-005X Vol. 2 Issue 3, March – 2018, Pages: 5-8 http://www.ijeais.org/ijaar 7 BIOMOLECULAR SPECTROSCOPY ,V59, P.23412352, 2003. [14] S.Rahmani, W.McCaffrey, J.Elliott, et al., IND ENG CHEM RES V42, P.4101-4108, 2003. [15] M.Rodriguez-Valverde, M.Cabrerizo-Vilchez, A. PaezDuenas , et al., COLLOID SURFACE A, V222, P. 233251, 2003 . [16] J.Brocks, R.Summons, R.Buick, et al., ORG GEOCHEM V34, P.1161-1175, 2003 [17] 7. J.Bryan, K.Mirotchnik, A.Kantzas, J CAN PETROL TECHNOL V42, P. 29-34, 2003 [18] A. H. Fawcett and T. McNally, Polymer, V 41, P. 53155326, 2000. [19] R.M. C. Santana, S. Manrich, Journal of Applied Polymer Science V88, P.2861-2867, 2003. [20] J.D. Ferry, "Viscoelastic Properties of Polymers", 3rd ed. ( Wiley, New York, 1980). [21] Mahmoud A.-Halim Abdel-Goad, PhD thesis, Muenster University, Germany, 2000. [22] A.Wilson, G.Fuchs, C.Scramoncin, D. Martin, J.P.Planche, Energy & Fuels, P.575-584, 2000. [23] F.Martinez-Boza, P. Partal, B.Conde, C.Gallegos, Energy & Fuels, V14, P. 131-137, 2000. Figure 1: Master curves of J' for bitumen/PE blend and bitumen base at T0 =25°C Figure 2: Master curves of J'' for bitumen/PE blend and bitumen base at T0 =25°C Figure 3: The shear creep for bitumen/PE blend and bitumen base at T0 =25°C 1 0 -4 1 0 -3 1 0 -2 1 0 -1 1 0 0 1 0 1 1 0 2 1 0 3 1 0 4 1 0 5 1 0 6 1 0 7 1 0 8 1 0 9 1 0 -7 1 0 -6 1 0 -5 1 0 -4 1 0 -3 ne a t b itum e n b it.-9 % P E J ' P a -1  ra d /s 10 -4 10 -3 10 -2 10 -1 10 0 10 1 10 2 10 3 10 4 10 5 10 6 10 7 10 8 10 9 10 -9 10 -8 10 -7 10 -6 10 -5 10 -4 10 -3 p ure b itum e n b it . -9 % P E J " P a -1  ra d /s 10 -6 10 -5 10 -4 10 -3 10 -2 10 -1 10 0 10 1 10 2 10 -7 10 -6 10 -5 10 -4 10 -3 10 -2 ne a t b itum e n b it . -9 % P E J t P a -1 t im e , s International Journal of Academic and Applied Research (IJAAR) ISSN: 2000-005X Vol. 2 Issue 3, March – 2018, Pages: 5-8 http://www.ijeais.org/ijaar 8 Figure 4: Master curves of the torque for bitumen/PE blend and bitumen base at T0 =25°C 10 -4 10 -3 10 -2 10 -1 10 0 10 1 10 2 10 3 10 4 10 5 10 6 10 7 10 8 10 9 10 -5 10 -4 10 -3 10 -2 ne a t b itum e n b it.-9 % P E to rq u e N M  ra d /s