The reactor of the experiment was made from stainless steel with the diameter of 25 cm and the height of 30 cm.  The liquid petroleum gas was used as a fuel in the reactor. The reactor was connected by the thermocouple that controls temperature variations at 410, 420, 430, and 450ºC. Raw material contained plastic bottles and waste caps, while the natural zeolite as a catalyst was dried and cut in dimensions of 3x3 cm. A gas as the reacted product was condensed using the first condenser, then the liquid product was collected. Uncondensed gaswas condensed again in the second condenser, then the liquid product was collected again. The volume of gas was calculated based on the water volume coming out of the gallon. Thiswas repeated with varied ratios of plastics to natural zeolite (67:33; 75:25; 80:20; and 83:17 wt%). Pyrolysis was run for two hours and every 20 minutes the sample was weighed to gauge the change inmass of gas and liquid. After 120 minutes, the solid sample was examined to identify the mass of final solid. Based on the research, at the temperature of 440ºC, the highest liquid yield was 68.42%. On the other hand, with the ratio of raw material to zeolite at 83:17 wt%, the largest yield of liquid was 87.31%. The liquid product in various temperature and comparisons of percentage of raw material to catalyst was found to meet diesel specifications based on The Decree of Director General of Fuels and Gas Year 200,8 Number 14,496 K/14/DJM/2,008.

high density polyethylene, polypropylene, pyrolysis, solar

Aboulkas, A., El harfi, K., & El Bouadili, A. (2010). Thermal degradation behaviors of polyethylene and polypropylene. Part I: Pyrolysis kinetics and mechanisms. Energy Convers. Manag., 51, 1363–1369.

Aboulkas, A., El harfi, K., El bouadili, A., Nadifiyine, M., Benchanaa, M., & Mokhlisse, A. (2009). Pyrolysis kinetics of olive residue/plastic mixtures by non-isothermal thermogravimetry. Fuel Process. Technol, 90, 722–728.

Åkesson, D., Krishnamoorthi, R., Foltynowicz, Z., Christéen, J., Kalantar, A., & Skrifvars, M. (2013). Glass Fibres Recovered by Microwave Pyrolysis as a Reinforcement for Polypropylene. Polymers and Polymers Composite, 21, 333–340.

Al-hartomy, O.A., Al-ghamdi, A.A., Farha, S.A., Said, A., Dishovsky, N., Mihaylov, M., Ivanov, M., & Ljutzkanov, L. (2014). Effect of the Carbon-Silica Reinforcing Filler Obtained from the Pyrolysis-cum-Water Vapour of Waste Green Tyres upon the Properties of Natural Rubber Based Composites. Progress in Rubber, Plastics, and Recycling Technology.31, 25–42.

Al-Salem, S.M., & Lettieri, P. (2010). Kinetic study of high density polyethylene (HDPE) pyrolysis. Chem. Eng. Res. Des., 88, 1599–1606.

Borusiewicz, R., & Kowalski, R. (2016). Volatile organic compounds in polyethylene bags—A forensic perspective. Forensic Sci. Int., 266, 462–468.

Chen, X., Wu, H., Luo, Z., Yang, B, Guo, S, & Yu, J. (2007). Synergistic Effects of Expandable Graphite With magnesium Hydroxide on the Flame Retardancy and Thermal Properties of Polypropylene, Polymer Engineering and Science, 47, 11, 1756-1760

Chin, B.L.F., Yusup, S., Al Shoaibi, A., Kannan, P., Srinivasakannan, C., & Sulaiman, S.A., (2014). Kinetic studies of co-pyrolysis of rubber seed shell with high density polyethylene. Energy Convers. Manag., 87, 746–753.

Chowlu, A.C.K., Reddy, P.K., & Ghoshal, A.K. (2009). Pyrolytic decomposition and model-free kinetics analysis of mixture of polypropylene (PP) and low-density polyethylene (LDPE). Thermochim. Acta 485, 20–25.

Donaj, P.J., Kaminsky, W., Buzeto, F., & Yang, W. (2012). Pyrolysis of polyolefins for increasing the yield of monomers’ recovery. Waste Manag., 32, 840–846.

Gogotov, I.N., & Barazov, S.K. (2014). The effect of ultraviolet light and temperature on the degradation of composite polypropylene. Int. Polym. Sci. Technol. 41, 55–58.

Moqadam, S.I, Mirdrikvand, M., Roozbehani, B., Kharaghani, A., & Shishehsaz, M.R. (2015). Polystyrene pyrolysis using silica-alumina catalyst in fluidized bed reactor. Clean Technol. Environ. Policy 17, 1847–1860.

Kaminsky, W., Schlesselmann, B., & Simon, C.M. (1996). Thermal degradation of mixed plastic waste to aromatics and gas. Polym. Degrad. Stab. 53, 189–197.

Kumar, S., & Singh, R. K. (2014). Pyrolysis Kinetics of Waste High-density Polyethylene using Thermogravimetric Analysis Pyrolysis Kinetics of Waste High-density Polyethylene using. Int. J. ChemTech Res., 6, 131–137.

Kumar, S., & Singh, R.K. (2011). Recovery of hydrocarbon liquid from waste high density polyethylene by thermal pyrolysis. Brazilian J. Chem. Eng., 28, 659–667.

Kunwar, B., & Cheng, H.N., Chandrashekaran, S.R., Sharma, B.K. (2016). Plastics to fuel: a review. Renew. Sustain. Energy Rev., 54, 421–428.

Levine, S.E., & Broadbelt, L.J. (2009). Detailed mechanistic modeling of high-density polyethylene pyrolysis: Low molecular weight product evolution. Polym.Degrad. Stab., 94, 810–822.

Mastellone, M.L., & Arena, U. (2002). Fluidized-bed pyrolysis of polyolefins wastes: Predictive defluidization model. AIChE J., 48, 1439–1447.

Muenpol, S., Yuwapornpanit, R., & Jitkarnka, S. (2015). Valuable petrochemicals, petroleum fractions, and sulfur compounds in oils derived from waste tyre pyrolysis using five commercial zeolites as catalysts: Impact of zeolite properties. Clean Technol. Environ. Policy, 17, 1149–1159.

Paradela, F., Pinto, F., Gulyurtlu, I., Cabrita, I., & Lapa, N. (2009). Study of the co-pyrolysis of biomass and plastic wastes. Clean Technol. Environ. Policy 11, 115–122.

Roozbehani, B., Motevassel, M., Mirdrikvand, M., Moqadam, S.I., & Kharaghani, A. (2017). Gasoline production from a polymeric urban disposal mixture using silica–alumina catalyst. Clean Technol. Environ. Policy, 19, 123–136.

Roozbehani, B., Sakaki, S.A., Shishesaz, M., Abdollahkhani, N., & Hamedifar, S. (2015). Taguchi method approach on catalytic degradation of polyethylene and polypropylene into gasoline. Clean Technol. Environ. Policy, 17, 1873–1882.

Sakaki, S.A., Roozbehani, B., Shishesaz, M., & Abdollahkhani, N. (2014). Catalytic degradation of the mixed polyethylene and polypropylene into middle distillate products. Clean Technol. Environ. Policy, 16, 901–910.

Schwarzinger, C., Gabriel, S., Beimann, S., & Buchberger, W. (2012). Quantitative analysis of polymer additives with MALDI-TOF MS using an internal standard approach. J. Am. Soc. Mass Spectrom., 23, 1120–1125.

Sharuddin, S.D.A., Abnisa, F., Daud, W.M.A.W., & Aroua, M.K. (2016). A review on pyrolysis of plastic wastes. Energy Convers. Manag.,115, 308–326.

Siddiqui, M.N., Redhwi, H.H., & Achilias, D.S. (2012). Recycling of poly(ethylene terephthalate) waste through methanolic pyrolysis in a microwave reactor. J. Anal. Appl. Pyrolysis, 98, 214–220.

Silvarrey, L.S.D., & Phan, A.N. (2016). Kinetic study of municipal plastic waste. Int. J. Hydrogen Energy 41, 16352–16364.

Syamsiro, M., Saptoadi, H., Norsujianto, T., Noviasri, P., Cheng, S., Alimuddin, Z., & Yoshikawa, K. (2014). Fuel oil production from municipal plastic wastes in sequential pyrolysis and catalytic reforming reactors. Energy Procedia, 47, 180–188.

Yuliansyah, A.T., Prasetya, A., Ramadhan, M.A.A. & Laksono, R. (2015), Pyrolysis of Plastics Waste to Produce Pyrolytic Oil As An Alternative Fuel. International Journal of Technology, 7, 1076-1083

Zhou, L., Luo, T., & Huang, Q. (2009). Co-pyrolysis characteristics and kinetics of coal and plastic blends. Energy Convers. Manag. 50, 705–710.