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- Title
Utilizing Pyrolysis of Plastic Debris for Refuse-Derived Fuel Production and Viable Substitute to Wood Debris.
- Authors
Sari, Mega Mutiara; Takanobu Inoue; Harryes, Regil Kentaurus; Septiariva, Iva Yenis; Kuriko Yokota; Notodarmodjo, Suprihanto; Shigeru Kato; Al Ghifari, Rizal Muhammad; Suhardono, Sapta; Suryawan, I. Wayan Koko; Prayogo, Wisnu; Arifianingsih, Nur Novilina
- Abstract
This research explores the viability of converting discarded Polyethylene Terephthalate (PET) plastic waste into a valuable resource through the implementation of pyrolysis and refuse-derived fuel (RDF) technologies. The objective is to assess the potential of PET charcoal waste as an efficient source for RDF generation, surpassing the energy recovery and recycling potential of PET waste. The study introduces three RDF variants: RDF PET100, RDF PET50, and RDF PET0. RDF PET100 is comprised entirely of PET charcoal, RDF PET50 combines 50% PET charcoal with 50% wood debris, and RDF PET0 consists entirely of wood debris. Comprehensive assessments of water content, ash content, and calorific value were conducted to evaluate the quality of these RDF formulations. Results indicate that RDF PET100 exhibits a water content of 2.63%, ash content of 0.73%, and calorific value of 5,976 MJ/kg. Similarly, RDF PET50 showcases a water content of 3.6%, ash content of 1.05%, and calorific value of 5,587 MJ/kg. RDF PET0 presents a water content of 7.51%, ash content of 1.36%, and calorific value of 4,198 MJ/kg. The outcomes underline the potential of PET plastic waste repurposing through RDF and pyrolysis techniques. Particularly, RDF PET100 emerges as a high-caliber fuel option characterized by its minimal water and ash content, coupled with a substantial calorific value. This innovation holds promise in mitigating plastic waste challenges, particularly pertinent in the context of Indonesia.
- Subjects
PLASTIC scrap; ENGINEERED log jams (Hydraulic engineering); PYROLYSIS; POLYETHYLENE terephthalate; REFUSE as fuel
- Publication
Ecological Engineering & Environmental Technology (EEET), 2023, Vol 24, Issue 8, p133
- ISSN
2719-7050
- Publication type
Article
- DOI
10.12912/27197050/171443