Studying Thermal Cracking Behavior of Vacuum Residue

Authors

  • Saleem Mohammad Alrubaye Al- Nahrain University, Engineering College, Iraq
  • Mohammed Saadi Hameed Al- Nahrain University, Engineering College, Iraq
  • Abdulkareem Dahash Affat Al- Nahrain University, Engineering College, Iraq

DOI:

https://doi.org/10.31699/IJCPE.2020.3.6

Keywords:

vacuum residue, cracking, coking, distillation

Abstract

   In the oil industry, the processing of vacuum residue has an important economic and environmental benefit. This work aims to produce industrial petroleum coke with light fuel fractions (gasoline, kerosene , gas oil) as the main product and de asphalted oil (DAO) as a side production from treatment secondary product matter of vacuum residue. Vacuum residue was produced from the bottom of vacuum distillation unit of the crude oil. Experimentally, the study investigated the effect of the thermal conversion process on (vacuum residue) as a raw material at temperature reaches to 500 °C, pressure 20 atm. and residence time for about 3 hours. The first step of this treatment is constructing a carbon steel batch reactor its volume about 700 ml, occupied with auxiliary control devices, joined together with an atmospheric distillation unit. The amounts of light fuel fraction products are 2 vol. % for light gasoline, 4 vol. % for heavy gasoline 17 vol. % for kerosene and 24 vol. % for diesel oil. The second step was the treatment the residue matter from first step, in order to separate the petroleum coke matter from asphaltene matter by solvent deasphalting matter (propane) to prepare de asphalted oil (DAO). The amount of de asphalted oil is about 15 vol. %, leaving asphaltene with impurities to precipitate at the bottom of the reactor and these materials consist of the petroleum coke structure. The petroleum coke separate and calcined at approximately (1000 - 1100) °C, to eliminate the reminder of volatile matter from the industrial coke and reach to commercial property.

References

D. Wang, L. jin, Y. Li. Hu. Upgrading of Heavy Oil with Chemical Looping partial Oxidation. Energy Fuel, 2019, pp. 256 – 270.

M. Ghashghaee, S. Shirvani, S. Kegnaes . steam catalytic cracking of fuel oil over a novel composite nano catalyst. J. Anal. Appl. Pyrol. 138, 2019, pp. 280 - 294.

M. S. Lopes. Savioli Lopes. Cracking of Petroleum Residues by Reactive Molecular Distillation. Procedia Engineering. 42, 2012, pp. 329- 34.

D. W. Kim, P. R. jon, S. Moon, C. H. Lee. Upgrading of petroleum vacuum residue using a hydrogen donor solvent with acid – treated carbon, Energ. Convers. Manage, 161 (2018) pp. 230 – 244.

D. I. Shishkova. Effect of feed stock properties on conversion and yields; Oil Gas- EUROPEAN MAGAZINE 43 (2):84-89, 2017.

J. G speight. Handbook of Petroleum Refining. Crc Press 2016.

S. Parkash. Petroleum fuels manufacturing Hand Book. The MC Graw –Hill, 2016

J. G Speight. Fouling in refineries. Gulf Professional Publishing, 2015.

G Speight. Hand book of petroleum product analysis .John Wiley & Sons, USA, 2015.

J G Speight. The Chemistry and Technology of Petroleum. CRC Press, 2014.

[G. Charles Hill. Introduction to chemical engineering kinetic & reactor design. New York; John Willy, 2014.

A. H. A.K Mohammed and S. Mohammed Obeyed, “Treatment of Slack Wax by Thermal Cracking Process”, ijcpe, vol. 15, no. 3, pp. 1-7, Sep. 2014.

E. Douglas; J G. Speight. Refining used Lubricating Oils. CRC Press, 2014.

Alkilani. A. Haitham, M. S. Taher A. AL-Sahhaf. fundamentals of petroleum refining ;first edition. Elsevier 2010.

Ebrahimi, s, J S Moghaddas. Study on Thermal Cracking Behavior of Petroleum Residue. Fuel 87 (8-9):1623-27, 2008.

LZ Pillion L. Z. Interfacial properties of petroleum products. CrC Press, 2007.

Syamsuddin, Y, B, A R Mohammed . "Thermal and catalytic cracking of petroleum residue oil." Eng. J. Univ. Qatar 18 (2005): 1-8.

B K haskara Rao. . Modern Petroleum Refining Processes. 4th ed., Indian Institute of Technology, 2004.

JH Gary, GE Handwerk, and MJ Kaiser. Petroleum refining: technology and economics. CRC press, 2007.

Downloads

Published

2020-09-30

How to Cite

Alrubaye, S. M., Hameed, M. S., & Affat, A. D. (2020). Studying Thermal Cracking Behavior of Vacuum Residue. Iraqi Journal of Chemical and Petroleum Engineering, 21(3), 45-49. https://doi.org/10.31699/IJCPE.2020.3.6

Publication Dates