The Optimization of Ozonolysis Reaction For Synthesis of Biopolyol From Used Palm Cooking Oil

Edy Purwanto; Lieke Riadi; Nathania Tamara I.; Mellisha Ika K.

Edy Purwanto Chemical Engineering Department, University of Surabaya, Raya Kalirungkut 60293, Surabaya, East Java, Indonesia
Lieke Riadi Chemical Engineering Department, University of Surabaya, Raya Kalirungkut 60293, Surabaya, East Java, Indonesia; Center for Environmental Studies, University of Surabaya, Raya Kalirungkut 60293, Surabaya, East Java, Indonesia
Nathania Tamara I. Chemical Engineering Department, University of Surabaya, Raya Kalirungkut 60293, Surabaya, East Java, Indonesia
Mellisha Ika K. Chemical Engineering Department, University of Surabaya, Raya Kalirungkut 60293, Surabaya, East Java, Indonesia

Keywords: Ozonolysis, Biopolyol, Hydroxyl value, Used cooking oil, palm oil

Abstract

Biopolyol is a raw material for synthesis of polyurethanes which is used as thermoset and thermoplastic materials, adhesives, rigid or non-rigid foams and also for coating. The utilization of waste edible oil as feedstock for synthesis of biopolyol has attracted some researchers. However, there is little attention focused on the application of ozone technology for synthesis of biopolyol from used cooking oil through ozonolysis reaction. Response surface methodology was performed to determine the optimal operating condition in the synthesis of biopolyol using ozone and sorbitol as a hydroxyl group source. The influence of input variables such as temperature, reaction time, molar ratio of oil to sorbitol and ozone concentration on hydroxyl value quantified was studied. The optimal condition was determined by high amount of hydroxyl value resulted from response surface method which used the experimental data. The ozonolysis reaction was conducted in a batch reactor equipped with agitator, tube sparger, thermocouple, reflux condenser and potassium iodide trap. Central composite design with four independent variables and one response variable was performed to determine the influence of independent variables on output variable of hydroxyl value of biopolyol. The hydroxyl value of polyol is a quadratic function of molar ratio of oil to methanol and a linear function of reaction temperature. The optimal operating condition was achieved at a temperature of 25℃, a reaction time of 5 hours, molar ratio of used cooking oil to sorbitol is 1:7 and ozone concentration about 4.8%.

References

1. Baber, T.M., Gravier, D., Lira, C.T., and Narayan, R. (2005). Application of catalytic ozone chemistry for improving biodiesel product performance, Biomacromolecules, 6, 1334-1344.
2. Bailey, A.E. (1951). Industrial oil and fat products, 2nd edn, Interscience Publisher, Inc, New York.
3. Benecke, H.P., Vijayendran, B.R., Garback, D.B., and Mitchel, K.P. (2008). Low cost and highly reactive biobased polyols: a co-product of the emerging biorefinery economy, Clean, 36, 694- 699.
4. Doddapaneni, K.K., Tatineni, R., Potumarthi, R., and Mangamoori, L.N. (2007). Optimization of media constituents through response surface methodology for improved production of alkaline proteases by serratia rubidaea, Journal of Chemical Technology and Biotechnology, 82, 721- 729.
5. Lligadas, G., Ronda, J.C., Galia, M., and Cadiz, V. (2006). Novel silicon- containing polyurethanes from vegetable oils as renewable resources. Synthesis and properties, Biomacromolecules, 7, 2420-2426.
6. Montgomery, D.C. (2005). Design and analysis of experiments, 6 th edn, John Wiley & Sons, Inc, New Jersey.
7. Ozone Solutions. (2012). Ozone solubility. Online: www.ozonesolutions.com/info/ozone- solubility.
8. Pechar, T.W., Sohn, S., Wilkes, G.L., Ghosh, S., Frazier, C.E., Fornof, A., and Long T.E. (2006). Characterization and comparison of polyurethane networks prepared using soybean-based polyols with varying hydroxyl content and their blends with petroleum-based polyols, Journal of Applied Polymer Science, 101, 1432-1443.
9. Petrovic, Z., Guo, A., and Javni, I. (2003). Process for the preparation of vegetable oil-based polyols and electroinsulating casting compounds created from vegetable oil-based polyols. United States Patent 6,573,354.
10. Tu, Y., Kiatsimkul, P., Suppes, G., and Hsieh, F. (2007). Physical properties of water-blown rigid polyurethane foams from vegetable oil-based polyols, Journal of Applied Polymer Science, 114, 2577-2583.
11. Wang, D., Zhang, G., Zhang, Y., Gao, Y., Zhao, Y., Zhou, C., Zhang, Q., and Wang, X. (2009). Synthesis, characterization, and properties of novel polyetherester polyols and developed polyurethanes, Journal of Applied Polymer Science, 103, 417-424.
12. Wang, J., and Wan, W. (2008). Optimization of fermentative hydrogen production process by response surface methodology, International Journal of Hydrogen Energy, 33, 6976- 6984.