SOYA YAĞI METİL ESTERLERİN ÜRETİMİ İÇİN BAZİK HETEROJEN KATALİZÖR TASARIMI

Year 2015, Volume: 3 Issue: 1, 401 - 406, 10.02.2015

Nebahat Değirmenbaşı Nezahat Boz

Abstract

Bu çalışmada, hidroksiapatit (HAP) katalizör destek malzemesi olarak birlikte çöktürme yöntemine göre hazırlandı. %25 potasyum hidroksit (KOH) HAP destek malzemesine ıslak emdirme yöntemi ile yüklenerek yapının bazikliği 1,6 mmol/g olarak bulundu. Elde edilen katı bazik katalizör soya yağının metanol ile transesterleşme tepkimesinden biyodizel (yağ asidi metil esterleri) üretimi için farklı sıcaklık aralığında (25-65°C) ve farklı alkol/yağ oranında (6/1-15/1) kütlece %3 katalizör miktarında 5 saat süre ile test edildi. Elde edilen soya yağ asidi metil esterlerinin saflığı ve yapısı ATR-IR spektroskopisi doğrulandı. KOH yüklenen HAP bazik katı katalizörü soya yağının transesterleşme tepkimesinde %93,3 metil ester verimi vererek oldukça başarılı bulundu.

Keywords

Hidroksiapatit, biyodizel, soya yağı, transesterleşme.

References

• 1. Van Gerpen, J., “Biodiesel processing and production”, Fuel Processing Technology, Cilt 86, 1097–1107, 2005.
• 2. Canakci, M., Van Gerpen, J., “Biodiesel production via acid catalysis”, Transactions of the ASAE, Cilt 42, 1203-1210, 1999.
• 3. Alcantara, R., Amores, J., Canoria, L., Fidalgo, E., Franco, M.J., Navarro, A., “Catalytic production of biodiesel from soy-bean oil, used frying oil and tallow”, Biomass and Bioenergy, Cilt 18, No 6, 515–527, 2000.
• 4. Du, W., Xu, Y., Zeng, J., Liu, D., “Novozym 435- catalysed transesterification of crude soya bean oils for biodiesel production in a solvent-free medium”, Biotechnology and Applied Biochemistry, Cilt 40, No 2, 187–190, 2004.
• 5. Marchetti, J.M., Miguel V.U., Errazu A.F., “Possible methods for biodiesel production”, Renewable and Sustainable Energy Reviews, Cilt 11, No 6, 1300- 1311, 2007.
• 6. Go, A.W., Sutanto, S., Nguyenthi, B.T., Cabatingan, L.K., Ismadji, S., Ju, Y., “Transesterification of soybean oil with methanol and acetic acid at lower reaction severity under subcritical conditions”, Energy Conversion and Management, Cilt 88, 1159-1166, 2014.
• 7. Souzo, S.P., Seabra, J.E.A., “Integrated production of sugarcane ethanol ve soybean biodiesel: Environmental and economic implications of fossil diesel displacement”, Energy Conversion and Management, Cilt 87, 1170-1179, 2014.
• 8. Xie, W., Huang, X., Li, H., “Soybean oil methyl esterss preparation using NaX zeolites loaded with KOH as a heterogenous catalyst”, Bioresource Technology, Cilt 98, 936-939, 2007.
• 9. Xie, W., Huang, X., “Synthesis of Biodiesel from Soybean Oil using Heterogeneous KF/ZnO Catalyst”, Catalysis Letters, Cilt 107, No 1-2, 53-59, 2006.
• 10. Liu, X., He, H., Wang, Y., Zhu, S., Piao, X., “Transesterification of Soybean Oil to Biodiesel using CaO as a Solid Base Catalyst”, Fuel, Cilt 87, No 2, 216-222, 2008.
• 11. Kouzu, M., Kasuno, T., Tajika, M., Sugimoto, Y., Yamanaka, S., Hidaka, J., “Calcium Oxide as a Solid Base Catalyst for Transesterification of Soybean Oil and its Application to Biodiesel Production”, Fuel, Cilt 87, 2798–2806, 2008.
• 12. Dossin, T.F., Reyniers, M.F., Berger, R.J., Marin, G.B., “Heterogeneously MgO-Catalyzed Transesterification for Fine-chemical and Biodiesel Industrial Production”, Applied Catalysis B: Environmental, Cilt 67, 136–148, 2006.
• 13. Liu, X., He, H., Wang, Y., Zhu, S., “Transesterification of Soybean Oil to Biodiesel Using SrO as a Solid Base Catalyst”, Catalysis Communications, Cilt 8, 1107–1111, 2007.
• 14. Xie, W., Peng, H., Chen, L., “Calcined Mg-Al hydrotalcites as solid base catalysts for methanolysis of soybean oil”, Journal of Molecular Catalysis A: Chemical, Cilt 246, 24-32, 2005.
• 15. Xie, W., Peng, H., Chen, L., “Transesterification of soybean oil catalyzed by potassium loaded on alümina as a solid-base catalyst”, Applied Catalysis A: General, Cilt 300, 67-74, 2006.
• 16. Değirmenbaşı, N., Kalyon, D.M., Birinci, E., “Biocomposites of nanohydroxyapatite with collagen and poly(vinyl alcohol)”, Colloids and Surfaces B: Biointerfaces, Cilt 48, 42–49, 2006.
• 17. Mori, K., Yamaguchi, K., Hara, T., Mizugaki, T., Ebiani, K., Kaneda,K., “Controlled Synthesis of Hydroxyapatite-supported Palladium Complexes as Highly Efficient Heterogeneous Catalysts”, Journal of the American Chemical Society, Cilt 124, No 39, 11572-11573, 2002.
• 18. Bai, R., Wang, S., Mei, F., Li, T., Li, G., “Synthesis of Glycerol Carbonate from Glycerol and Dimethyl Carbonate Catalyzed by KF Modified Hydroxyapatite”, Journal of Industrial and Engineering Chemistry, Cilt 17, No 4, 777-781, 2011. 19. European Standard of TS-EN 14103, ‘Fat and oil derivatives-Fatty Acid Methyl Esters (FAME) - Determination of ester and linolenic acid methyl ester contents’, April 2003.
• 20. Boz, N., Değirmenbaşı, N., Kalyon, D.M., “Conversion of Biomass to Fuel: Transesterification of Vegetable Oil to Biodiesel using KF Loaded Nano-γ-Al2O3
• as Catalyst”, Applied Catalysis B: Environmental, Cilt 89, 590-596, 2009.
• 21. Boz, N., Değirmenbaşı, N., Kalyon, D.M., “Transesterification of canola oil to biodiesel using calcium bentonite functionalized with K compounds”, Applied Catalysis B: Environmental, Cilt 138-139, 236-242, 2013.
• 22. Degirmenbasi, N., Boz, N., Kalyon, D.M., “Biofuel Production via Transesterification using Sepiolitesupported Alkaline Catalysts, Applied Catalysis BEnvironmental, Cilt 150-151, 147-156, 2014.
• 23. Knothe, G., Kenar J.A., “Determination of the Fatty Acid Profile by 1H-NMR Spectroscopy”, European Journal of Lipid Science and Technology, Cilt 106, No 2, 88-96, 2004.
• 24. Linck, Y.G., Killner, M.N.M., Danieli, E., Blümich, B., “Mobile Low-Field 1H-NMR Spectroscopy Desktop Analysis of Biodiesel Production”, Applied Magnetic Resonance, Cilt 44, No 1-2, 41- 53, 2013.