Open AccessEvaporated Palm Oil Cracking To Gasoline Over Zeolite Catalysts
Author(s) -
Tirena Bahnur Siregar,
Nor Aishah Saidina Amin
Publication year - 2012
Publication title -
jurnal teknologi/jurnal teknologi
Language(s) - English
Resource type - Journals
eISSN - 2180-3722
pISSN - 0127-9696
DOI - 10.11113/jt.v52.130
Subject(s) - gasoline , nuclear chemistry , fluid catalytic cracking , chemistry , zeolite , space velocity , gas analyzer , physics , catalysis , environmental chemistry , organic chemistry , selectivity
Peretakan bermangkin minyak kelapa sawit kepada gasolin menggunakan H–ZSM–5 dan H–Beta dijalankan pada tekanan atmosfera dan kadar alir mengikut berat 2.5 jam–1. Suhu tindak balas ditetapkan dalam julat 450°C to 525°C. Mangkin yang dikalsinkan telah dicirikan menggunakan teknik pembelauan sinar X, penjerapan piridina–spektrofotometri inframerah dan penjerapan nitrogen. Hasil cecair dan gas dianalisis menggunakan kromatografi gas (FID) dan (TCD). Peningkatan suhu tidak balas meninggikan penukaran minyak kelapa sawit. Penukaran minyak kelapa sawit dan kepemilihan gasolin tertinggi diperolehi dengan mangkin H–ZSM–5, masing–masing ialah 96.12% berat dan 29.92% berat. Walaupun penukaran minyak kelapa sawit dan kepemilihan gasolin untuk kedua–dua mangkin adalah tinggi, tetapi H–ZSM–5 menunjukkan hasil yang lebih baik berbanding H–Beta pada semua suhu. Gasolin yang dihasilkan menggunakan H–ZSM–5 mempunyai kandungan naftena yang tinggi, diikuti oleh isoparafin, olefin, aromatik dan sedikit paraffin, manakala gasolin yang terhadil menggunakan H–Beta mengandungi olefin, naftena, paraffin dan aromatik. Hasil sampingan utama adalah gas yang terdiri daripada komponen C1–C3 menggunakan H–ZSM–5 dan C3–C4 menggunakan H–BetaKata kunci: Zeolit; H–ZSM–5; H–Beta; peretakan; minyak kelapa sawit; gasolin The catalytic cracking of palm oil to gasoline over H–ZSM–5 and H–Beta was studied in fixed bed reactor operated at atmospheric pressure and weight hourly space velocity (WHSV) of 2.5 h–1. The reaction temperature was varied between 450°C to 525°C. The calcined catalysts were characterized using X–Ray Diffraction (XRD), Pyridine Adsorption–Infrared Spectrophotometry (Py–IR) and Nitrogen Adsorption (NA) methods. The liquid and gaseous products were analyzed using (FID) and (TCD) gas chromatography respectively. Increase in reaction temperature led to higher palm oil conversion. The highest conversion and gasoline selectivity obtained at 525°C were 96.12 wt% and 29.92 wt% respectively with H–ZSM–5. Although the conversion and the gasoline selectivity of both catalysts was high, but H–ZSM–5 performed better than H–Beta at all temperature range. Gasoline produced using H–ZSM–5 consisted mainly of naphthenes beside isoparaffins, olefins, aromatics and a small amount of paraffins, while the gasoline obtained by using H–Beta contained olefins, naphthenes, paraffins and aromatics. Gas was the major side product, which consisted mainly of C1–C3 for using H–ZSM–5 and C3–C4 compounds for using H–Beta. Key words: Zeolite; H–ZSM–5; H–Beta; cracking, palm oil; gasoline