Petroleum is still the primary energy used in the world. Its diminishing production is the trigger to find alternative energy to replace it. Biofuel is an alternative energy that has the potential to replace petroleum because it is renewable, environmentally friendly, and easy raw material. Waste such as used cooking oil can be used as raw material for making biofuels. The low price can reduce the cost of biofuel production. The conversion of oil into biofuel can be done using catalytic cracking with natural zeolite as a catalyst. This study aims to determine the optimum conditions for making biofuel from used cooking oil and determine its physical and chemical properties. The catalytic cracking process is carried out using an autoclave reactor. Used cooking oil and natural zeolite were introduced into the reactor, and the reaction was carried out by varying the time (1, 2, 3 hours), temperature (325, 350, 375^oC), catalyst concentration (3, 5, 7%), and catalyst size. The product is distilled to produce biofuel (liquid), gas, and residue. The optimization results show that 3 hours, a temperature of 375^oC, a catalyst concentration of 7%, and a catalyst size of 180µm are the optimum conditions for catalytic cracking with 44.94% biofuel yield. The resulting biofuel contains 73.48% hydrocarbons and 26.52% fatty acids. The hydrocarbon composition consists of 19.32% gasoline, 12.82% kerosene, and 35.11% diesel. The density of the biofuel produced is 0.8835g/mL, the flashpoint is 68^oC, and the pourpoint is 27^oC.

Biofuel, hydrocarbon, catalytic cracking, used cooking oil, natural zeolite

Alfanaar, R., Yuniati, Y. & Rismiarti, Z. (2017). Studi Kinetika Dan Isoterm Adsorpsi Besi(III) Pada Zeolit Alam Dengan Bantuan Gelombang Sonikasi. EduChemia (Jurnal Kimia dan Pendidikan), 2(1), 63–72. doi: 10.30870/educhemia.v2i1.1297.

Anonim. (2020). Executive summary mineral kementerian ESDM.

ASTM D93-80. 1980.

ASTM D97-98. 1987

Aziz, I., Yolanda, T., Adhani L., & Saridewi, N. (2019). Catalytic cracking of Jatropa curcas oil using natural zeolite of Lampung as a catalyst. IOP Conference Series: Earth and Environmental Science, 299(1), 6–13. doi: 10.1088/1755-1315/299/1/012065.

Aziz, I., Tafdila, M.A., Nurbayti. S., Adhani. L., & Permata. W. (2019). Upgrading Crude Biodiesel dari Minyak Goreng Bekas menggunakan Katalis H-Zeolit. Jurnal Kimia Valensi, 5(1), 79–86. doi: 10.15408/jkv.v5i1.10493.

Aziz, I., Kurnianti., Saridewi, L., Adhani, L., & Permata, W., (2020). ‘Utilization of Coconut Shell as Cr2O3 Catalyst Support for Catalytic Cracking of Jatropha Oil into Biofuel. Jurnal Kimia Sains dan Aplikasi, 23(2), 39–45. doi: 10.14710/jksa.23.2.39-45.

Febriyanti, E., Roesyadi, A. & Prajitno, D. H. (2020). Konversi Minyak Biji Nyamplung (Callophyllum Inophyllum Linn ) Menjadi Biofuel dengan Katalis Berbasis NiMo / γ-Al2 O3. Berkala Saintek, 8(3), 89–95.

Fitriyah. (2016). Interkalasi Xilenol Orange Pada Zeolit Alam Lampung sebagai Elektroda Zeolit Termodifikasi. Jurnal Kimia dan Pendidikan, 1(2), 162–175.

Anonim. 2019. Produksi Minyak Bumi dan Gas Alam. https://www.bps.go.id.

Istadi, I., Riyanto, T., Buchori, L., Anggoro, D.D., Pakpahan, A.W.S., & Pakpahan, A.J. (2021). Biofuels production from catalytic cracking of palm oil using modified hy zeolite catalysts over a continuous fixed bed catalytic reactor. International Journal of Renewable Energy Development, 10(1), 149–156. doi: 10.14710/ijred.2021.33281.

Jaroenkhasemmeesuk, C., Prasertpong, P., Thanmongkhon, Y., &

Tippayawon, N. (2017). Simplex Lattice Approach to Optimize Yields of Light Oil Products from Catalytic Cracking of Bio-Oil with Mixed Catalysts. Chemical Engineering Communications, 204(6), 677–688. doi: 10.1080/00986445.2017.1302942.

Jaroenkhasemmeesuk, C., Diego, M. E., | Tippayawong, N., Ingham, D. B., Pourkashanian, M. (2018). Simulation analysis of the catalytic cracking process of biomass pyrolysis oil with mixed catalysts: Optimization using the simplex lattice design. International Journal of Energy Research, 42(9), 2983–2996. doi: 10.1002/er.4023.

Kadarwati, S. & Wahyuni, S. (2015). Characterization and performance test of palm oil based bio-fuel produced via ni/zeolite-catalyzed cracking process. International Journal of Renewable Energy Development, 4(1), 32–38. doi: 10.14710/ijred.4.1.32-38.

Li, L., Quan, K., Xu, J., Liu, F., Liu, S., Yu, S., Xie, C., Zhang, B., & Ge, X. (2014). Liquid hydrocarbon fuels from catalytic cracking of rubber seed oil using USY as catalyst. Fuel, 123, 189–193.

Hazzamy, M.A., & Zahrina, I. (2014). Pembuatan Biofuel Dari Minyak Goreng Bekas Melalui Proses Catalytic Cracking Dengan Katalis Fly Ash. Jurnal Online Mahasiswa, 1(1).

De Oliveira, B. F. H. de França, D. F., Corrêa, N. C. F., Ribeiro, N. F. D., & Mauricio Velasquez, M. (2021). Renewable diesel production from palm fatty acids distillate (Pfad) via deoxygenation reactions. Catalysts, 11(9), 1–16. doi: 10.3390/catal11091088.

Riyadhi, A., Yulizar, Y. & Susanto, B. H. (2020). Catalytic conversion of beef tallow with MgO derived from MgCO3for biofuels production. IOP Conference Series: Materials Science and Engineering, 902(1). doi: 10.1088/1757-899X/902/1/012049.

Savitri, S., Nugraha, A. S. & Aziz, I. (2016). Pembuatan Katalis Asam (Ni/γ-Al2O3) dan Katalis Basa (Mg/γ-Al2O3) untuk Aplikasi Pembuatan Biodiesel dari Bahan Baku Minyak Jelantah. Jurnal Kimia Valensi, 2(1), 1–10. doi: 10.15408/jkv.v2i1.3104.

Sundaryano, A. & Budiyanto. (2010). Pembuatan bahan bakar hidrokarbon cair melalui reaksi cracking minyak pada limbah cair pengolahan kelapa sawit. Jurnal Teknologi Industri Pertanian, 20(1).

Tambun, R., Saptawaldi, R. P., Nasution, M. A. & Gusti, O. N. (2016). Pembuatan Biofuel dari Palm Stearin dengan Proses Perengkahan Katalitik Menggunakan Katalis ZSM-5’, Jurnal Rekayasa Kimia & Lingkungan. 11(1), 46. doi: 10.23955/rkl.v11i1.4902.

Wibowo, S., Efiyanti, L. & Pari, G. (2020). Catalytic and thermal cracking of bio-oil from oil-palm empty fruit bunches, in batch reactor. Indonesian Journal of Chemistry, 20(5), 1000–1009. doi: 10.22146/ijc.44076.