Energy Inputs on the Production of Plastic Products

Marczak, Halina

doi:10.12911/22998993/151815

Artykuł - szczegóły

Tytuł artykułu

Energy Inputs on the Production of Plastic Products

Autorzy

Marczak Halina

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.12911/22998993/151815

Warianty tytułu

Języki publikacji

Abstrakty

The paper considers plastic products in terms of energy consumption at two stages of their life cycle, i.e. at the stage of production of virgin polymers and at the stage of processing polymers into a finished product. Energy intake places were indicated and energy needs related to the production of polymer products were assessed. This allowed to indicate which polymer production and processing processes into finished products are particularly energy-intensive. The research shows that the greater the amount of energy accumulated in the plastic during its production, the greater the importance of this plastic in the post-consumer phase as a recyclable material. Recycling of waste plastics allows the use of this energy and reduces the consumption of virgin raw materials. Primary polymers were compared in terms of the energy efficiency index of their production process. This indicator is the quotient of the calorific value of the polymer and the energy consumption in its production. It shows how much of the energy input during the production of primary plastic can be recovered from the thermal processing of the waste plastic. The highest indicator value was obtained for polyethylene and polypropylene. It was found shown that the total energy consumption (converted to primary energy) of the PET virgin polymer production process and its processing into packaging reaches the value of 109.2–115.2 MJ/kg. This is almost five times the calorific value of this polymer.

Słowa kluczowe

energy consumption primary polymers plastics energy storage polymer processing

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2022

Tom

Vol. 23, nr 9

Strony

146--156

Opis fizyczny

Bibliogr. 40 poz., rys., tab.

Twórcy

autor

Marczak Halina

h.marczak@pollub.pl

Department of Sustainable Transport and Sources of Propulsion, Lublin University of Technology, ul. Nadbystrzycka 36, 20-618 Lublin, Poland

https://orcid.org/0000-0003-2282-9963

Bibliografia

1. Ahsby M.F. 2020. Materials and the environment: eco-informed material choice. Third edition. Elsevier/Butterworth-Heinemann.
2. Alsabri A., Al-Ghamdi S.G. 2020. Carbon footprint and embodied energy of PVC, PE, and PP piping: Perspective on environmental performance. Energy Reports, 6, 364–370.
3. Alsabri A., Tahir F., Al-Ghamdi S.G. 2021. Life-cycle assessment of polypropylene production in the Gulf Cooperation Council (GCC) Region. Polymers, 13(21), 1–14.
4. Benavides P.T., Dunn J.B., Han J., Biddy M., Markham J. 2018. Exploring comparative energy and environmental benefits of virgin, recycled, and bio-derived PET bottles. ACS Sustainable Chem. Eng., 6(8), 9725–9733.
5. Benchaita T. 2013. Greenhouse gas emissions from new petrochemical plants. Inter-American Development Bank. Environmental Safeguards Unit. Technical Note No. IDB-TN-562.
6. Castro-Aguirre E., Iñiguez-Franco F., Samsudin H., Fang X., Auras R. 2016. Poly(lactic acid) - Mass production, processing, industrial applications, and end of life. Advanced Drug Delivery Reviews, 107(15), 333–366.
7. Dias D.S., Crespi M.S., Ribeiro C.A., Kobelnik M. 2021. Evaluation of the thermal decomposition of blends prepared with poly(3-hydroxybutyrate) (PHB) and recyclable ethylene poly-terephthalate (RPET). J. Therm. Anal. Calorim., 143, 3447–3457.
8. Engelbeen F. Plastics - Environmental aspects. Indian Institute of Science Centre for Ecological Sciences, http://ces.iisc.ernet.in/hpg/envis/plasdoc612.html (6.01.2022).
9. Franklin Associates, a division of Eastern Research Group, Inc. 2010. Final report cradle-to-gate life cycle inventory of nine plastic resins and four polyurethane precursors. Prairie Village, Kansas.
10. Gervet B. 2007. The use of crude oil in plastic ma king contributes to global warming. INSA Lyon, France, Luleå University of Technology, Sweden.
11. Ghanta M., Fahey D., Subramaniam B. 2014. Environmental impacts of ethylene production from diverse feedstocks and energy sources. Applied Petrochemical Research, 4, 167–179.
12. Industry, trade end service. Statistics on the production of manufactured goods. 2022. Eurostat, https://ec.europa.eu/eurostat/data/database (27.03.2022).
13. International Aluminium Institute. 2021. Statistics, https://international-aluminium.org/statistics/primary-aluminium-smelting-energy-intensity/ (01.04.2022).
14. Iron and Steel. Tracking report-November. 2021. International Energy Agency (IEA).
15. Iwko J., Wróblewski J. 2019. Experimental study on energy consumption in the plasticizing unit of the injection molding machine. International Scientific Journal „Industry 4.0”, 5, 241–245.
16. Kaminsky W. 2021. Chemical recycling of plastics by fluidized bed pyrolysis. Fuels Communications, 8, 1–10.
17. Kossakowski P. 2013. Aluminum - an ecological material. Przegląd Budowlany, 10, 36–41. (in Polish)
18. Kozera-Szałkowska A. 2019. Polymer market – production, consumption, waste management. Polimery, 64, 751–758. (in Polish)
19. Leisegang T., Meutzner F., Zschornak M., Münchgesang W., Schmid R., Nestler T., Eremin R.A., Kabanov A.A., Blatov V.A., Meyer D.C. 2019. The aluminum-ion battery: A sustainable and seminal concept? Frontiers in Chemistry, May, 7, 1–21.
20. Low energy plastics processing. European Best Practice Guide. 2006. Reduced Energy Consumption in Plastics Engineering (RECIPE). Intelligent Energy Europe Programme.
21. Marczak H. 2019. Analysis of the energetic use of fuel fractions made of plastic waste. Journal of Ecological Engineering, 20(8), 100–106.
22. Martelaro N. 2016. Energy use in US steel manufacturing, Stanford University. 2016. Available online: http://large.stanford.edu/courses/2016/ph240/martelaro1/ (accessed on 12 May 2022).
23. Migdał A.R., Kijeński J., Kawalec A., Kędziora A., Rejewski P., Śmigiera E. 2014. Energy recovery of plastic waste materials. Chemik, 68(12), 1056–1073. (in Polish)
24. Natural gas price statistics. 2021. Eurostat, https://ec.europa.eu/eurostat/statistics-explained/ (14.03.2022).
25. Natural gas prices. 2022. U.S. Energy Information Administration (EIA), https://www.eia.gov/dnav/ng/ng_pri_sum_dcu_nus_m.htm (14.03.2022).
26. Obaidat M., Al-Ghandoor A., Phelan P, Villalobos R., Alkhalidi A. 2018. Energy and exergy analyses of different aluminum reduction technologies. Sustainability, 10, 1–21.
27. Plastic Europe. 2021. Plastics – the Facts 2021. An analysis of European plastics production, demand and waste data.
28. Polyethylene terephthalate (PET) (bottle grade). 2017. Committee of PET Manufacturers in Europe (CPME).
29. Ptak S., Jakóbiec J. 2016. Crude oil as the main energy-industrial raw material. Nafta-Gaz, 6, 451–460. (in Polish)
30. Rashid M.M., Sarker M. 2015. Dirty waste plastics to crude oil production for refinery. World Journal of Science and Technology Research, 2, 1–13.
31. Sahajwalla V., Zaharia M., Kongkarat S., Rahman M., Saha-Chaudhury N, O’Kane P., Dicker J., Skidmore C., Knights D. 2012. Recycling end-of-life polymers in an arc furnace steelmaking process: fundamentals of polymer reactions with slag and metal. Energy Fuels, 26(1), 58–66.
32. Schepp C., Tabrizi M., Tucker T., Nicol J., English B., Kent R. 2006. Plastic Industry. Energy Best Practice. Guidebook. Focus on Energy.
33. Singh A., Rorrer N.A., Nicholson S.R., Erickson E., DesVeaux J.S., Avelino A.F.T., Lamers P., Bhatt A., Zhang Y., Avery G. 2021. Techno-economic, life-cycle, and socioeconomic impact analysis of enzymatic recycling of poly(ethylene terephthalate). Joule, 5, 2479–2503.
34. Sorek A., Borecki M., Ostrowska-Popielska P. 2012. Selected plastic waste as a source of alternative fuels in the metallurgical industry. Prace Instytutu Metalurgii Żelaza, 4, 47–57. (in Polish)
35. Statistical Yearbook of Industry – Poland. 2021. Central Statistical Office (GUS), Warsaw. (in Polish)
36. Tamoor M., Samak N., Maohuma Y., Xing J. 2022. The cradle-to-cradle life cycle assessment of polyethylene terephthalate: Environmental perspective. Molecules, 27, 1599, 1–26.
37. Thiriez A., Gutowski T. 2006. An environmental analysis of injection molding. Proceedings of the 2006 IEEE International Symposium on Electronics and the Environment. USA.
38. Tressaud A. 2019. Fluorine: A paradoxical element. Elsevier Science Publishing Co Inc.
39. Wróbel G., Chmielnicki B., Bortel K. 2015. Changes of selected sroperties of LD PE mixtures with degradable recyclates after their composting. Przetwórstwo Tworzyw, 1(163), 65–75. (in Polish)
40. Vlachopoulos J. 2009. An assessment of energy savings derived from mechanical recycling of polyethylene versus new feedstock. A report prepared for the World Bank. Version 3.2. Canada.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-3c85632a-8a78-437c-8abe-bbb56cc67fbd