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Gasification characteristics of waste plastics (SRF) in a bubbling fluidized bed: Effects of temperature and equivalence ratio

Author

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  • Han, Si Woo
  • Lee, Jeong Jae
  • Tokmurzin, Diyar
  • Lee, Seok Hyeong
  • Nam, Ji Young
  • Park, Sung Jin
  • Ra, Ho Won
  • Mun, Tae-Young
  • Yoon, Sang Jun
  • Yoon, Sung Min
  • Moon, Ji Hong
  • Lee, Jae Goo
  • Kim, Young-Min
  • Rhee, Young Woo
  • Seo, Myung Won

Abstract

This study investigates air gasification properties of SRF with high content of residual mixed waste plastic in a 1 kg/h lab scale bubbling fluidized bed gasifier. Gasifier internal diameter is 0.114 m and its height is 1 m. Silica sand particles with a mean diameter of 400 μm is used as the bed material. During the gasification experiments the effect of bed temperature is determined in the range of 600–900 °C and the effect of air-to-fuel equivalence ratio (ER) is investigated in the range of 0.15–0.30. Gas analysis is conducted using a non-dispersive infrared analyzer and gas chromatograph. As the operating temperature and ER increases, the gas yield increases, and tar yield decreases. The yield of CO, CH4, H2, and C2H2 in the gas product increases with temperature, whereas those of CO2, C2–C3 hydrocarbons decreases. The increase in ER decreases the concentrations of CO, CH4, H2, and C2–C3 hydrocarbons and increases the CO2 in the gas product. H2/CO ratio substantially increases with rising temperature and decreases with rising ER. Carbon conversion efficiency (CCE) and cold gas efficiency reach peak at 800 °C and ER of 0.25.

Suggested Citation

  • Han, Si Woo & Lee, Jeong Jae & Tokmurzin, Diyar & Lee, Seok Hyeong & Nam, Ji Young & Park, Sung Jin & Ra, Ho Won & Mun, Tae-Young & Yoon, Sang Jun & Yoon, Sung Min & Moon, Ji Hong & Lee, Jae Goo & Kim, 2022. "Gasification characteristics of waste plastics (SRF) in a bubbling fluidized bed: Effects of temperature and equivalence ratio," Energy, Elsevier, vol. 238(PC).
    • Handle: RePEc:eee:energy:v:238:y:2022:i:pc:s0360544221021927
    DOI: 10.1016/j.energy.2021.121944
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    References listed on IDEAS

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    1. Cho, Min-Hwan & Mun, Tae-Young & Choi, Young-Kon & Kim, Joo-Sik, 2014. "Two-stage air gasification of mixed plastic waste: Olivine as the bed material and effects of various additives and a nickel-plated distributor on the tar removal," Energy, Elsevier, vol. 70(C), pages 128-134.
    2. Nakamura, Shunsuke & Kitano, Shigeru & Yoshikawa, Kunio, 2016. "Biomass gasification process with the tar removal technologies utilizing bio-oil scrubber and char bed," Applied Energy, Elsevier, vol. 170(C), pages 186-192.
    3. Cho, Min-Hwan & Mun, Tae-Young & Kim, Joo-Sik, 2013. "Production of low-tar producer gas from air gasification of mixed plastic waste in a two-stage gasifier using olivine combined with activated carbon," Energy, Elsevier, vol. 58(C), pages 688-694.
    4. Zhou, Hui & Meng, AiHong & Long, YanQiu & Li, QingHai & Zhang, YanGuo, 2014. "An overview of characteristics of municipal solid waste fuel in China: Physical, chemical composition and heating value," Renewable and Sustainable Energy Reviews, Elsevier, vol. 36(C), pages 107-122.
    5. Di Gregorio, F. & Zaccariello, Lucio, 2012. "Fluidized bed gasification of a packaging derived fuel: energetic, environmental and economic performances comparison for waste-to-energy plants," Energy, Elsevier, vol. 42(1), pages 331-341.
    6. Hamel, Stefan & Hasselbach, Holger & Weil, Steffen & Krumm, Wolfgang, 2007. "Autothermal two-stage gasification of low-density waste-derived fuels," Energy, Elsevier, vol. 32(2), pages 95-107.
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    Cited by:

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