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Manuscript ID : JEST-1801-4133 (R2) Visit : 150 Page: 98 - 109

10.22034/jest.2020.33711.4133

Article Type: Original Research

Recycling the Spent Catalysts of Claus Unit in Natural Gas Refineries and Their Application for Synthesis of Composite Adsorbents Coated by Polypyrrole for the removal of lead ions

Subject Areas : Heavy metal

Nima Fallah 1 , Tayebeh Johari 2 , mohammad Toosi 3 , mohammad hasan Peyrovi 4

1 - Department of Chemistry, Qaemshahr Branch, Islamic Azad University, Qaemshahr, Iran.
2 - Department of Chemistry, Saveh Branch, Islamic Azad University, Saveh, Iran
3 - Department of Chemistry, Qaemshahr Branch, Islamic Azad University, Qaemshahr, Iran. *(Corresponding Author)
4 - Faculty of Chemistry Science and Petroleum, Department of Physical Chemistry, University of Shahid Beheshti, Tehran

Received: 2018-01-23 Accepted : 2018-04-25 Published : 2020-05-21

Keywords: Polypyrrole, Recycling the Spent Catalyst, activated alumina, Lead, Composite adsorbent,

Abstract :

Background and Objective: Catalytic processes in oil and gas industries are very important for refining, purification and production of useful compounds. Regeneration of spent catalysts is interested due to their environmental problems as solid wastes in the refineries. Activated alumina is a very useful catalyst in gas refinery for conversion of hydrogen sulfide to the elemental sulfur in Claus unit.In this paper regeneration of spent catalyst of Claus process in Sulfur Recovery Unit (SRU) and application of it for synthesis of polypyrrole/Al2O3 composite as an adsorbent of lead ion was investigated. Method: Catalyst regeneration was performed via washing by water or caustic washing and then thermal process. Characterization and analysis of catalysts were performed by XRF, XRD, FTIR, and BET measurements. Polypyrrole /Al2O3 composite was synthesized by in situ polymerization and used for removal of lead ions in batch experiments and different values of pH, lead concentration and temperature. Findings: Results showed that regeneration process caused to removal of impurities and sulfur without any change in the catalyst structure. Specific area of catalyst increased from 84 m2/g in spent catalyst to 186 m2/g in regenerated sample while the sulfur content decreased from 2.53% to 0.005-0.007%. Discussion and Conclusion: The results indicated that the composite showed high ability for lead removal. Adsorption behavior was determined as Langmuir isotherm and pseudo-second order kinetic.  

References:


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_||_

  1. Dufresne, P., 2007. Hydroprocessing catalysts regeneration and recycling. Appl. Catal. A, Vol. 322, pp. 67-75.
    2.
  2. Zare Nezhad, B., Hosseinpour, N., 2008. Effect of O2 Concentration on the Reaction Furnace Temperature and Sulfur Recovery Using a TSWEET ® Process Simulator. Appl. Thermal Eng, Vol. 28, pp. 738-744.
    3.
  3. Karge, H. G., Taniecki, M., Zibkek, M., 1998. UV-visible spectroscopic investigations of the modified claus reaction on NaX zeolite catalysts. J. Catal., Vol. 109, pp. 252-262.
    4.
  4. Datta, A., Cavel, R. G., 1985. Claus catalysis. 3. An FTIR study of the sequential adsorption of sulfur dioxide and hydrogen sulfide on the alumina catalyst. J.  Phys. Chem., Vol. 89, pp. 454-457.
    5.
  5. Bernardo, C. A., Trimm, D. L., 1978. Structural factors in the deposition of carbon on nickel. Carbon, Vol. 14, pp. 225-228.
    6.
  6. Wolf, E. E., Alfani, F., 1982. Catalysts Deactivation by Coking. Catal. Rev. Sci. Eng., Vol. 24, pp. 329-371.
    7.
  7. Choi, K. Y., Cant, N. W., 1998. Trimm, D. L.; Gasification of carbonaceous particulates.  J. Chem. Technol. Biotechnol., Vol. 71, pp. 57-60.
    8.
  8. Walker, P. L., Rusinko, J. F., Austin, L. G., 1959. Gas reactions of carbon. Adv. Catal., Vol. 1, pp. 133-221.
    9.
  9. Bernardo, C. A., Trimm, D. L., 1979, The kinetics of gasification of carbon deposited on nickel catalysts. Carbon, Vol. 17, pp. 115-120.
    10.
  10. McCarty, J. G., Wise, H., 1979. Hydrogenation of surface carbon on alumina-supported nickel.  J. Catal., Vol. 57, pp. 406-416.
    11.
  11. Heck, R. M., Farrauto, R. J., 1994. Catalytic Air Pollution Control, Commercial Technology, VanNostrand Reinhold, New York.
    12.
  12. Trimm, D.L., 1980. Design of Industrial catalysts. Elsevier, Amsterdam.
    13.
  13. Mallakpour, S., Khadem, E., 2015. Recent development in the synthesis of polymer nanocomposites based on nano-alumina, Progress Polymer Sci., Vol 51, pp. 74-93.
    14.
  14. Zavareh, S., Zarei, M., Darvishi, Azizi, F. A., 2015. As (III) adsorption and antimicrobial properties of Cu–chitosan/alumina nanocomposite, Chem. Eng. J., Vol. 273, pp. 610-621.
    15.
  15. Yahyaei, B., Azizian, S., Mohammadzadeh, A., Pajohi-Alamoti, M., 2014. Preparation of clay/alumina and clay/alumina/Ag nanoparticle composites for chemical and bacterial
    16.
  16. Tajizadegan, H., Jafari, M., Rashidzadeh, M., Saffar-Teluri, A., 2013. A high activity adsorbent of ZnO–Al2O3 nanocomposite particles: Synthesis, characterization and dye removal efficiency, Appl. Surf. Sci., Vol. 276, pp. 317-322.
    17.
  17. Mahapatra, A., Mishra, B. G., Hota, G., 2013. Adsorptive removal of Congo red dye from wastewater by mixed iron oxide–alumina nanocomposites, Ceramics Int., Vol. 39, pp. 5443-5451
    18.
  18. Gupta, V. K., Agarwal, S., Saleh, T. A., 2011. Synthesis and characterization of alumina-coated carbon nanotubes and their application for lead removal, J. Hazard. Mater., Vol. 185, pp. 17-23.
    19.
  19. Nomngongo, P. N., Ngila, J. C., 2014. Functionalized nanometer-sized alumina supported micro-solid phase extraction coupled to inductively coupled plasma mass spectrometry for preconcentration and determination of trace metal ions in gasoline samples, RSC Advances, Vol. 4, pp. 46257-46264.
    20.
  20. Lemster, K., Delporte, M., Graule, T., Kuebler, J., 2007. Activation of alumina foams for fabricating MMCs by pressureless infiltration, Ceramics Int., Vol. 33, pp. 1179–1185.
    21.

 

 

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