论文信息 - Recovery of oil from waste poly(ethylene terephthalate) without producing any sublimate materials

Recovery of oil from waste poly(ethylene terephthalate) without producing any sublimate materials

Abstract When household waste plastics are thermally decomposed, sublimate materials such as terephthalic acid and benzoic acid are produced, which cause serious pipe blocking in plants built for the degradation of the waste. The sublimate materials produced have been successfully decomposed using FeOOH catalyst. The main products were acetophenone, phenol, benzene and carbon dioxide. Ni(OH) 2 and NiO showed low activity, and Fe 2 O 3 was inactive. A reaction mechanism is proposed and kinetic equations derived. These model equations were found to represent the experimental data well. FeOOH catalyst was transformed into porous Fe 2 O 3 with pores of about 10–50 nm in diameter after steam treatment above 773 K. Many active sites are thought to be generated on the surface of the pores. As expected from this result, an iron ore containing a large amount of FeOOH was found to show high activity for the decomposition of terephthalic acid, whereas the activity of an iron ore containing Fe 2 O 3 was negligible. This suggests that an iron ore with a large amount of FeOOH can be used as a cheap catalyst with high mechanical strength for the degradation of poly(ethylene terephthalate) without producing any sublimate.

[1] Ahmad Rahman Songip,et al. Kinetic studies for catalytic cracking of heavy oil from waste plastics over REY zeolite , 1994 .

[2] T. Isobe,et al. Infrared Absorption Spectrum of Gaseous CF3CO Radical; Recording on a Rapid-Scan Infrared Spectrometer , 1976 .

[3] Yoshikazu Sugimoto,et al. Conversion of Polyethylene to Transportation Fuels through Pyrolysis and Catalytic Cracking , 1994 .

[4] K. Hashimoto,et al. Degradation of waste poly(ethylene terephthalate) in a steam atmosphere to recover terephthalic acid and to minimize carbonaceous residue , 1997 .

[5] C. Nicolella,et al. HCl formation via pyrolytic degradation of polyvinyl chloride (PVC): an empirical approach to kinetic modelling , 1994 .

[6] Giorgio Montaudo,et al. Primary thermal degradation mechanisms of PET and PBT , 1993 .

[7] T. Ikemura,et al. Effect of branching of polyolefin backbone chain on catalytic gasification reaction , 1989 .

[8] Ching-Yuan Chang,et al. Two‐Stage pyrolysis model of PVC , 1994 .

[9] A. R. Songip,et al. Production of high-quality gasoline by catalytic cracking over rare-earth metal exchanged Y-type zeolites of heavy oil from waste plastics , 1994 .