10.1007/s40095-015-0167-z

Conversion of waste plastics into low-emissive hydrocarbon fuels through catalytic depolymerization in a new laboratory scale batch reactor

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  • P. Senthil Kumar*1,
  • M. Bharathikumar1,
  • C. Prabhakaran1,
  • S. Vijayan2,
  • K. Ramakrishnan1,
  1. Department of Chemical Engineering, SSN College of Engineering, Chennai, 603 110, IN
  2. Department of Mechanical Engineering, SSN College of Engineering, Chennai, 603 110, IN
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Published in Issue 2015-02-25

How to Cite

Senthil Kumar, P., Bharathikumar, M., Prabhakaran, C., Vijayan, S., & Ramakrishnan, K. (2015). Conversion of waste plastics into low-emissive hydrocarbon fuels through catalytic depolymerization in a new laboratory scale batch reactor. International Journal of Energy and Environmental Engineering, 8(2 (June 2017). https://doi.org/10.1007/s40095-015-0167-z
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Abstract

Abstract Pyrolysis of waste plastic is a prospective way of conversion of waste plastic into low-emissive hydrocarbon fuel. The present research is focused on the conversion of waste plastic into low-emissive hydrocarbon fuel by two process namely vacuum and catalytic cracking (activated carbon, activated carbon with granulated charcoal and activated carbon with calcium oxide). Waste plastic materials viz., polyethylene, polypropylene, polystyrene and polyethylene terephthalate were collected from local convenience store packing materials. Waste plastic material pyrolysis was conducted as individual plastics and as mixed feed in a new laboratory scale batch reactor. Hydrocarbon molecules from the basic materials are split under the impact of catalyst inside the reactor in 70–240 °C. The reduction of process takes place from 500–600 °C to 240 °C in the presence of catalyst. The analyses of pyrolysis products suggested that it can be used as a viable alternative to motor fuel. It was observed that the yield was better in the case of individual plastic material as opposed to mixed feed in all cases except polypropylene under non-catalysed vacuum process. The comparison of the GC-FID (TPH) report of the obtained oil with that of the commercial petrol clearly proves that the prepared oil is composed of petrol components.

Keywords

  • Waste plastics,
  • Pyrolysis,
  • Alternative fuel,
  • Catalytic conversion,
  • Hydrocarbon,
  • Petrol
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