Kinetics of Polyethylene Terephthalate (PET)and Polystyrene (PS) Dynamic Pyrolysis
Thermo-chemical treatment (TCT) such as pyrolysis
is getting recognized as a valid route for (i) materials and valuable
products and petrochemicals recovery; (ii) waste recycling; and (iii)
elemental characterization. Pyrolysis is also receiving renewed
attention for its operational, economical and environmental
advantages. In this study, samples of polyethylene terephthalate
(PET) and polystyrene (PS) were pyrolysed in a microthermobalance
reactor (using a thermogravimetric-TGA setup). Both
polymers were prepared and conditioned prior to experimentation.
The main objective was to determine the kinetic parameters of the
depolymerization reactions that occur within the thermal degradation
process. Overall kinetic rate constants (ko) and activation energies
(Eo) were determined using the general kinetics theory (GKT)
method previously used by a number of authors. Fitted correlations
were found and validated using the GKT, errors were within ± 5%.
This study represents a fundamental step to pave the way towards the
development of scaling relationship for the investigation of larger
scale reactors relevant to industry.
[1] A. Valavanidis, N. Iliopoulos, G. Gotsis, K. Fiotakis, 2008. "Persistent
free radicals, heavy metals and PAHs generated in particulate soot
emissions and residue ash from controlled combustion of common types
of plastic". J Hazard Mater, 156(1-3); 277-284.
[2] APC, 2008. ÔÇÿAmerican Plastics Council, Facts and figures-. Arlington
VA 22209, Technical paper.
[3] APM EU, 2008. ÔÇÿAssociation of Plastic Manufacturers in Europe, An
analysis of plastics consumption in Europe-. Code: 2002 APME.
[4] Waste Watch, 2003. ÔÇÿPlastics in the UK economy: A guide to polymer
use and the opportunities for recycling-. Final report of the Programme
of sustainable use (UK); Waste Watch group.
[5] Clark, J.H., Hardy, J.J.E., 2004. ÔÇÿTowards sustainable chemical
manufacturing: Polylactic acid - A sustainable polymer-, In: Azapagic,
A., Perdon, S., and Clift, R. (eds), Sustainable development in practice:
Case studies for engineers and scientists, Wiley 1st edition.
[6] PEU, 2008. ÔÇÿPlastics Europe, The compelling facts about plastics 2007:
An analysis of plastics production, demand and recovery for 2007 in
Europe-. Published by the Association of Plastics Manufactures (Plastics
Europe), October.
[7] Smith, B. 2002. ÔÇÿPlastics recycling in the UK-. Final report, Valuplast.
[8] Ward, P., 2009. ÔÇÿPicking up plastic-. J Waste Resour Manage, CIWM
June; 62-63.
[9] Parfitt, J., 2002. ÔÇÿAnalysis of household waste composition and factors
driving waste increases-. Waste and Resources Action Programme
(WRAP) for strategy unit, Government Cabinet Office, London,
England (UK).
[10] Kaminsky, W., Schlesselmann, B., Simon, C., 1995. ÔÇÿOlefins from
polyolefins and mixed plastics by pyrolysis-. J Anal App Pyrolysis, 32;
19-27.
[11] Andel, L., Kusy, J., Vales, J., Safarova, M., 2009. -Pyrolysis process of
waste polyethyleneterephthalate-. Chem Prod Process Model, 4(1); 1-6.
[12] Ahrenfeldt J., 2007. ÔÇÿCharacterization of biomass producer gas as fuel
for stationary gas engines in combined heat and power production-. PhD
Thesis, Department of Chemical Engineering, Technical University of
Denmark, Lyngby, Denemark.
[13] Mastral, J.F., Berrueco, C., Ceamanos, J., 2007. ÔÇÿTheoretical prediction
of product distribution of the pyrolysis of high density polyethylene-. J
Anal App Pyrolysis, 80(2); 427-438.
[14] Al-Salem, S.M., Lettieri, P., Baeyens, J., 2009. -Recycling and recovery
routes of plastic solid waste (PSW): A review-, Waste Manage, 29(10):
2625-2643.
[15] Al-Salem, S.M., Lettieri, P., Baeyens, J., 2010. -Petrochemicals recovery
through polyethylene (PE) pyrolysis: Maximizing product yields via
isothermal and dynamic kinetics-, In: Proc Energy from Biomass and
Waste UK Conference and Exhibition, London (England), UK, 26th-27th
January.
[16] Al-Salem, S.M., Lettieri, P., Baeyens, J., 2009. -Thermal treatment of
different grades and types of polyethylene (PE) wasted articles-. In: Proc
8th World Congress of Chemical Engineering, Montreal (Quebec), pp. 1-
4, Canada, 23rd-27th August.
[17] Al-Salem, S.M., Lettieri, P., Baeyens, J., (2009). -Thermal pyrolysis of
High Density Polyethylene (HDPE)-. In: Proc 9th European Gasification
Conference: Clean energy and chemicals, Organized by the Institute for
Chemical Engineers (IChemE): Energy Conversion Subject Group,
D├╝sseldorf, Germany, 23rd-25th March.
[18] Ray, R., Bhattacharya, P., Chowdhury, R., 2004. ÔÇÿSimulation and
modelling of vegetable market wastes pyrolysis under progressive
deactivation condition-. Can J Chem Eng, 82(3); 566-579.
[19] Al-Salem, S.M., Lettieri, P., Baeyens, J., 2010. -The valorization of
plastic solid waste (PSW) by primary to quaternary routes: From re-use
to energy and chemicals-. Prog Energy Combust Sci, 36(1): 103-129.
[20] Al-Salem, S.M., Lettieri, P., Baeyens, J., (2009). -Kinetics and product
distribution of end of life tyres (ELTs) pyrolysis: A novel approach in
polyisoprene and SBR thermal cracking-. J Hazard Mat, 172(2-3); 1690-
1694.
[21] Yang, J., Gupta, M., Roy, X., Roy, C., 2004. Study of tire particle
mixing in a moving and stirred bed vacuum pyrolysis reactor, Can J
Chem Eng, 82(3); 510-519.
[22] Oh, S.C., Jun, H.C., Kim, H.T., 2003. Thermogravimetric evaluation for
pyrolysis kinetics of styrene-butadiene rubber, J Chem Eng Jpn, 36(8);
1016-1022.
[23] Coats, A.W., Redfern, J.P., 1964. Kinetic parameters from
thermogravimetric data. Nature, 201(4914); 68-69.
[24] Martin-Gullon, I., Esperanza, M. and Font, R., 2001. Kinetic model for
the pyrolysis and combustion of poly-(ethylene terephthalate) (PET). J
Anal App Pyrolysis, 58-59; 635-650.
[25] Saha, B., Ghoshal, A.K., 2005. Thermal degradation kinetics of
poly(ethylene terephthalate) from waste soft drinks bottles. Chem Eng J,
111(1); 39-43.
[26] Kim, S., Kim, S., 2004. Pyrolysis characteristics of polystyrene and
polypropylene in a stirred batch reactor. Chem Eng J, 98(1-2); 53-60.
[27] Bouster, C., Vermande, P., Veron, J., 1980. Study of the pyrolysis of
polystyrenes: I. Kinetics of thermal decomposition. J Anal App
Pyrolysis, 1(4); 297-313.
[28] Martin-Gullon, I., Esperanza, M. and Font, R., 2001. Kinetic model for
the pyrolysis and combustion of poly-(ethylene terephthalate) (PET). J
Anal App Pyrolysis, 58-59; 635-650.
[29] R.K. Agrawal, 1992. Analysis of non-isothermal reaction kinetics. Part I:
Simple reactions. Thermochim Acta, 203; 93-110.
[1] A. Valavanidis, N. Iliopoulos, G. Gotsis, K. Fiotakis, 2008. "Persistent
free radicals, heavy metals and PAHs generated in particulate soot
emissions and residue ash from controlled combustion of common types
of plastic". J Hazard Mater, 156(1-3); 277-284.
[2] APC, 2008. ÔÇÿAmerican Plastics Council, Facts and figures-. Arlington
VA 22209, Technical paper.
[3] APM EU, 2008. ÔÇÿAssociation of Plastic Manufacturers in Europe, An
analysis of plastics consumption in Europe-. Code: 2002 APME.
[4] Waste Watch, 2003. ÔÇÿPlastics in the UK economy: A guide to polymer
use and the opportunities for recycling-. Final report of the Programme
of sustainable use (UK); Waste Watch group.
[5] Clark, J.H., Hardy, J.J.E., 2004. ÔÇÿTowards sustainable chemical
manufacturing: Polylactic acid - A sustainable polymer-, In: Azapagic,
A., Perdon, S., and Clift, R. (eds), Sustainable development in practice:
Case studies for engineers and scientists, Wiley 1st edition.
[6] PEU, 2008. ÔÇÿPlastics Europe, The compelling facts about plastics 2007:
An analysis of plastics production, demand and recovery for 2007 in
Europe-. Published by the Association of Plastics Manufactures (Plastics
Europe), October.
[7] Smith, B. 2002. ÔÇÿPlastics recycling in the UK-. Final report, Valuplast.
[8] Ward, P., 2009. ÔÇÿPicking up plastic-. J Waste Resour Manage, CIWM
June; 62-63.
[9] Parfitt, J., 2002. ÔÇÿAnalysis of household waste composition and factors
driving waste increases-. Waste and Resources Action Programme
(WRAP) for strategy unit, Government Cabinet Office, London,
England (UK).
[10] Kaminsky, W., Schlesselmann, B., Simon, C., 1995. ÔÇÿOlefins from
polyolefins and mixed plastics by pyrolysis-. J Anal App Pyrolysis, 32;
19-27.
[11] Andel, L., Kusy, J., Vales, J., Safarova, M., 2009. -Pyrolysis process of
waste polyethyleneterephthalate-. Chem Prod Process Model, 4(1); 1-6.
[12] Ahrenfeldt J., 2007. ÔÇÿCharacterization of biomass producer gas as fuel
for stationary gas engines in combined heat and power production-. PhD
Thesis, Department of Chemical Engineering, Technical University of
Denmark, Lyngby, Denemark.
[13] Mastral, J.F., Berrueco, C., Ceamanos, J., 2007. ÔÇÿTheoretical prediction
of product distribution of the pyrolysis of high density polyethylene-. J
Anal App Pyrolysis, 80(2); 427-438.
[14] Al-Salem, S.M., Lettieri, P., Baeyens, J., 2009. -Recycling and recovery
routes of plastic solid waste (PSW): A review-, Waste Manage, 29(10):
2625-2643.
[15] Al-Salem, S.M., Lettieri, P., Baeyens, J., 2010. -Petrochemicals recovery
through polyethylene (PE) pyrolysis: Maximizing product yields via
isothermal and dynamic kinetics-, In: Proc Energy from Biomass and
Waste UK Conference and Exhibition, London (England), UK, 26th-27th
January.
[16] Al-Salem, S.M., Lettieri, P., Baeyens, J., 2009. -Thermal treatment of
different grades and types of polyethylene (PE) wasted articles-. In: Proc
8th World Congress of Chemical Engineering, Montreal (Quebec), pp. 1-
4, Canada, 23rd-27th August.
[17] Al-Salem, S.M., Lettieri, P., Baeyens, J., (2009). -Thermal pyrolysis of
High Density Polyethylene (HDPE)-. In: Proc 9th European Gasification
Conference: Clean energy and chemicals, Organized by the Institute for
Chemical Engineers (IChemE): Energy Conversion Subject Group,
D├╝sseldorf, Germany, 23rd-25th March.
[18] Ray, R., Bhattacharya, P., Chowdhury, R., 2004. ÔÇÿSimulation and
modelling of vegetable market wastes pyrolysis under progressive
deactivation condition-. Can J Chem Eng, 82(3); 566-579.
[19] Al-Salem, S.M., Lettieri, P., Baeyens, J., 2010. -The valorization of
plastic solid waste (PSW) by primary to quaternary routes: From re-use
to energy and chemicals-. Prog Energy Combust Sci, 36(1): 103-129.
[20] Al-Salem, S.M., Lettieri, P., Baeyens, J., (2009). -Kinetics and product
distribution of end of life tyres (ELTs) pyrolysis: A novel approach in
polyisoprene and SBR thermal cracking-. J Hazard Mat, 172(2-3); 1690-
1694.
[21] Yang, J., Gupta, M., Roy, X., Roy, C., 2004. Study of tire particle
mixing in a moving and stirred bed vacuum pyrolysis reactor, Can J
Chem Eng, 82(3); 510-519.
[22] Oh, S.C., Jun, H.C., Kim, H.T., 2003. Thermogravimetric evaluation for
pyrolysis kinetics of styrene-butadiene rubber, J Chem Eng Jpn, 36(8);
1016-1022.
[23] Coats, A.W., Redfern, J.P., 1964. Kinetic parameters from
thermogravimetric data. Nature, 201(4914); 68-69.
[24] Martin-Gullon, I., Esperanza, M. and Font, R., 2001. Kinetic model for
the pyrolysis and combustion of poly-(ethylene terephthalate) (PET). J
Anal App Pyrolysis, 58-59; 635-650.
[25] Saha, B., Ghoshal, A.K., 2005. Thermal degradation kinetics of
poly(ethylene terephthalate) from waste soft drinks bottles. Chem Eng J,
111(1); 39-43.
[26] Kim, S., Kim, S., 2004. Pyrolysis characteristics of polystyrene and
polypropylene in a stirred batch reactor. Chem Eng J, 98(1-2); 53-60.
[27] Bouster, C., Vermande, P., Veron, J., 1980. Study of the pyrolysis of
polystyrenes: I. Kinetics of thermal decomposition. J Anal App
Pyrolysis, 1(4); 297-313.
[28] Martin-Gullon, I., Esperanza, M. and Font, R., 2001. Kinetic model for
the pyrolysis and combustion of poly-(ethylene terephthalate) (PET). J
Anal App Pyrolysis, 58-59; 635-650.
[29] R.K. Agrawal, 1992. Analysis of non-isothermal reaction kinetics. Part I:
Simple reactions. Thermochim Acta, 203; 93-110.
@article{"International Journal of Chemical, Materials and Biomolecular Sciences:53507", author = "S.M. Al-Salem and P. Lettieri", title = "Kinetics of Polyethylene Terephthalate (PET)and Polystyrene (PS) Dynamic Pyrolysis", abstract = "Thermo-chemical treatment (TCT) such as pyrolysis
is getting recognized as a valid route for (i) materials and valuable
products and petrochemicals recovery; (ii) waste recycling; and (iii)
elemental characterization. Pyrolysis is also receiving renewed
attention for its operational, economical and environmental
advantages. In this study, samples of polyethylene terephthalate
(PET) and polystyrene (PS) were pyrolysed in a microthermobalance
reactor (using a thermogravimetric-TGA setup). Both
polymers were prepared and conditioned prior to experimentation.
The main objective was to determine the kinetic parameters of the
depolymerization reactions that occur within the thermal degradation
process. Overall kinetic rate constants (ko) and activation energies
(Eo) were determined using the general kinetics theory (GKT)
method previously used by a number of authors. Fitted correlations
were found and validated using the GKT, errors were within ± 5%.
This study represents a fundamental step to pave the way towards the
development of scaling relationship for the investigation of larger
scale reactors relevant to industry.", keywords = "Kinetics, PET, PS, Pyrolysis, Recycling,Petrochemicals.", volume = "4", number = "6", pages = "393-9", }
