Solid Fuel Char Production via Pyrolysis Process of Oily Sludge Produced as a Resulted in Storage Tanks at North Refineries Company Baiji

Authors

  • Mahmod A. Abdulqader Oil Products Distribution Company (OPDC), Salahuldeen Branch
  • Omar Abed Habeeb North Refineries Company, Baiji
  • Mohammed Sarhan Dheab Ministry of Oil / Petroleum Research and Development Center
  • Shihab Ezzuldin M. Saber North Refineries Company, Baiji
  • Asaad Owayez Rabet Ministry of Oil / Petroleum Research and Development Center
  • Gazwan J. Mohammed Oil Products Distribution Company (OPDC), Salahuldeen Branch
  • A. H. Saleh North Refineries Company, Baiji

DOI:

https://doi.org/10.52716/jprs.v12i1(Suppl.).631

Keywords:

Oily Sludge, Pyrolysis Process, Char, Calorific Value.

Abstract

The oily sludge contains a toxics material. It has an impact effect to the environment and worker’s health. Therefore, treatment the residue oily sludge in the refineries storage tanks and convert it to useful product, is an important task. Oily sludge (OS) sample was obtained from North Refineries Company (NRC) Baiji which produced about 3000-3500 m3/ year. In this study, different range of pyrolysis temperatures have been applied (300, 500, 700, and 900 °C). The parameters have been investigated the efficiency of char produced from OS. The operation conditions of (20 g, 700 °C, and 1.5 h, under N2 pressure) are investigated. The calorific value was enhanced from 9.125 to 17.247 MJ.kg-1 with an increased rate ~ 89.0 %.  The fuel ratio was increased from 0.78 of OS to 0.97 around 24.35 % increased percentage of char at 700 °C. Finally, the energy recovery was enhanced at maximum value 1.909 % of char at 700 °C. The results show the fuel properties were upgraded to burn with a small amount of CO2.

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Published

2022-04-21

How to Cite

(1)
Abdulqader, M. A.; Habeeb, O. A.; Dheab, M. S.; Saber, S. E. M.; Rabet, A. O.; Mohammed, G. J.; Saleh, A. H. Solid Fuel Char Production via Pyrolysis Process of Oily Sludge Produced As a Resulted in Storage Tanks at North Refineries Company Baiji. Journal of Petroleum Research and Studies 2022, 12, 199-210.