The productivity of Indonesia's tire industry is expected to be higher following the growth of domestic and global motor vehicle production. Along with that, waste used tires that are not used in the environment are increasing. Rubber-based tires, is one type of synthetic polymer (Polystyrene). Polystyrene cannot be easily recycled so that the processing of polystyrene waste must be done properly so as not to harm the environment. Polystyrene pyrolysis process is one way to minimize the polystyrene waste. The pirlolysis process is carried out with temperature operating conditions of 400 oC, weight of tire rubber 3000 grams with variations of catalyst 2%, 4% and 6% for 3 hours. The results showed that the more catalysts used the% CHP Conversion produced would be greater, the best results on the 6% catalyst were as much as 41.073%. Based on the results of the analysis using GC-MS, Used inner tire pyrolysis oil has the following hydrocarbon chains: (C₁-C₅) as much as 0.33%, (C₅-C₁₂) as much as 88.96% and (C₁₀-C₂₈) 10.71%. Hydrocarbon compounds contained in the oil from used tire pyrolysis contain many aromatic compounds

Arita. S., Assalami. A., Naibaho. D. I. 2015. Proses Pembuatan Bahan Bakar Cair dengan Memanfaatkan Limbah Ban Bekas Menggunakan Katalis Zeolit. Jurnal Teknik Kimia, 02(21) : 8-14.

Asron F., Falaah., Adi Cifriadi. 2012. Pemanfaatan Limbah Ban Bekas Dengan Menggunakan Teknologi Pirolisis. Jurnal Warta Perkaretan : 103- 107.

BPS. 2017. Produksi Minyak Bumi dan gas Alam 1996-2015.

Buekens, A.G., Huang, H. 1998. Catalytic plastics cracking for recovery of gasolinerange hydrocarbons from municipal plastic wastes. Resources, Conservation and Recycling, 23 : 163-181.

Damayanthi. R dan Martini. R. 2009. Proses Pembuatan Bahan Bakar Cair dengan Memanfaatkan Limbah Ban Bekas Menggunakan Katalis Zeolit Y dan ZSM-5. Jurnal Teknik Kimia. Semarang : Universitas Diponegoro

Handono Roy. 2017. Pembuatan Bahan Bakar Cair dengan Memanfaatkan Limbah Ban Bekas Menggunakan Katalis dari Limbah Bekas Perengkahan Minyak Bumi PT. Pertamina Ru III Dengan Metode Pirolisis. Palembang : Universitas Muhammadiyah Palembang.

Hutomo. S. G., Winarno. J. 2015. Studi Karakteristik Dekomposisi Termal. Temperatur Tinggi Ban Bekas Untuk Mendapatkan Bahan Bakar Gas Alternatif. Jurnal Teknik, 1(5) : 40-46.

Kementrian perindustrian. 2018. Industri Ban Kian Prospektif.

Merve Sogancioglu., Esra Yel., Gulnare Ahmetli. 2017. Investigation of the Effect of Polystyrene (PS) Waste Washing Process and Pyrolysis Temperature on (PS) Pyrolysis Product Quality. Energy Procedia, 118 : 189–194.

Rodiansono., Trisunaryati. W., Triyono. 2007. Pembuatan, Karakterisasi dan Uji Aktifitas Katalis NiMo/Z pada Reaksi Hidrorengkah Fraksi Sampah Plastik Menjadi Fraksi Bensin. Jurnal Berkala MIPA : 2-17.

Sa’diyah. Khalimatus., Juliastuti., S.R. 2015. Pengaruh Jumlah Katalis Zeolit Alam Pada Produk Proses Pirolisis Limbah Plastik Polipropilen (PP). JBAT, 4(2): 40-45.

Saputra. A. E., Rahman. M. Aminy. Y.A. 2006. Produksi Bahan Bakar Ramah Lingkungan Melalui Proses Pirolisis Limbah Ban. Jurnal JPE, 20(2): 26-31.

Setiadi, dan Pertiwi, A., 2007. Preparasi dan Karakteristik Zeolite Alam untuk Konversi Senyawa Abe menjadi Hidrokarbon. Jurnal Teknik Kimia.

Sholihah Atti. 2018. Analisis Kramatografi Gas. BPPT

Syamsiro. M. 2015. Kajian Pengaruh Penggunaan Katalis Terhadap Kualitas Produk Minyak Hasil Pirolisis Sampah Plastik. Jurnal Teknik, 5(1): 47-56.

Syamsiro. M., Sulistiawati. Y., Ridwan. M., Dwicahyo. M. 2016. Studi Pirolisis Sampah Ban untuk Produksi Bahan Bakar Minyak Alternatif bagi Industri Kecil dan Menengah. Jurnal Riset Daerah, 15(3): 2511-2521.