Oil Sorption Performance of Sorbent Materials Examined Under Static and Dynamic Conditions



Abstract Views
928

Downloads
1060

Citations

Share

##plugins.themes.bootstrap3.article.sidebar##

Submitted Jun 6, 2021
Published Aug 13, 2021
10.24018/ejeng.2021.6.5.2490

Abstract viewed = 928 times

Table of Contents

##plugins.themes.bootstrap3.article.main##

Oil spill cleanup and subsequent restoration of the environment is majorly a function of spill cleanup methods applied. Some of these methods, though efficient, are, however, very expensive and require more personnel for their application and relative deployment in the field. The study was aimed at examining the efficiency of a locally and readily available, eco-friendly and low cost agricultural waste (coconut husk coir) as sorbent materials for spilled engine oil cleanup under static and dynamic marine water conditions. The sorbent material was prepared and used in three forms: raw coconut husk coir (CHC), modified coconut husk coir (MCHC), and reused coconut husk coir (RCHC). Under static and dynamic marine water conditions, oil sorption batch equilibrium experiments were used to study the engine oil sorption capacity and efficiency of the sorbent. Effects of sorbent dosage and sorption times on the oil sorption and efficiency of CHC, MCHC, and RCHC were studied and determined. At a constant sorption time of 60 minutes and varying sorbent dosages of 2-8 /320 ml of engine oil-marine water concentration, MCHC exhibited the highest oil sorption efficiency of 61.18% and 44.33% for dynamic and static conditions, CHC had 55.61% and 38.50% for dynamic and static conditions, whereas RCHC had 41.66% and 26.04% for dynamic and static conditions, respectively. It is statistically deduced from the results that sorption times and sorbent dosages have significant effects on the sorption efficiency of experimental coir for spilled engine oil removal. Though there is a need for proper blending or modifications of the sorbent material to enhance its affinity to oil and hydrophobicity, there are enough potentials in the materials for mild marine water current spilled engine oil cleanup.

Keywords: Engine Oil, Hydrophobicity, Oil Sorption, Sorbent Material, Static and Dynamic Conditions

Downloads

Download data is not yet available.

References

  1. Solomon, G. M. and Janssen, S. (2010). Health Effects of the Oil Spill, JAMA: The Journal of the American Medical Association, Vol. 304, pp. 1118-1119.
     Google Scholar
  2. Chen, J. and Denison, M. S. (2011). The Deepwater Horizon Oil Spill: Environmental Fate of the Oil and the Toxicological Effects on Marine Organism, Journal of Young Investigators, Vol. 21, pp. 84–95.
     Google Scholar
  3. Idris, J., Eyu, G. D., Ahmad, Z., Chukwuekezie, C.S. (2013). Oil Spills and Sustainable Clean Up Approach, Austrialian Journal of Basic and Applied Sciences, Vol. 7(14), pp. 272-280.
     Google Scholar
  4. Rengasamy, R., Das, D. and Praba Karan, C. (2011). Study of Oil Sorption Behavior of Filled and Structured Ffiber Assemblies made from Polypropylene, Kapok and Milkweed, Journal of Hazardous Materials, vol. 186, pp. 526-532.
     Google Scholar
  5. Wei, Q. F., Mather, R. R. and Fotheringham, A. F. (2005), Oil Sorbent, Journal of Oil Gas Science and Technology, Vol 62, pp. 407.
     Google Scholar
  6. Al-Majed, A. A., Adebayo, A. R., Hossain, M. E. (2012). A Sustainable Approach to Controlling Oil Spills, Journal of Environmental Management, Vol. 113, (2012), pp. 213-227.
     Google Scholar
  7. Choi, H.M., and Cloud, R.M. (1992). Use of natural sorbents for oil spill cleanup, Environmental Science and Technology, 26(4), pp. 772-776.
     Google Scholar
  8. Anthony, W. S. (1994). Absorption of Oil with Cotton Products and Kenaf. Appl. Eng. Agri., Vol.10, pp. 357-361.
     Google Scholar
  9. Lim, T. and Huang, X. (2007). Evaluation of Kapok (Ceiba Pentandra (L.) Gaertn.) as a natural Hollow Hydrophobic–oleophilic Fibrous Sorbent for Oil Spill Cleanup, Chemosphere, vol. 66, pp. 955-963.
     Google Scholar
  10. Ismail, A. S. (2015). Preparation and Evalution of Fatty-sawdust as a Natural Bio polymer for Oil Spill Sorption, Chemistry Journal, Vol. 5(5), pp. 80-85.
     Google Scholar
  11. Ukotije-Ikwut, P. R., Idogun, A. K., Iriakuma, C.T., Aseminaso, A., Obomanu, T. (2016). A Novel Method for Adsorption using Human Hair as a Natural Oil Spill Sorbent, International Journal of Scientific and Engineering Research, Vol. 7(8), pp 1754-1764.
     Google Scholar
  12. Ifelebuegu, A. O. and Momoh, Z. (2015). Evaluation of the adsorptive properties of Coconut Husk for Oil spill cleanup. Proceedings of International Conference on Advances in Applied Science and Environmental Technology.
     Google Scholar
  13. ASTM 1998c, F726-99: Standard Test Method for Sorbent Performance of Adsorbents in: Annual Book of ASTM Standards, ASTM committee on Standards, West Conshohocken, PA, 1998.
     Google Scholar
  14. Ali, N., Rehan, A. M., Hussain, A., Memon, H. (2014), Investigation of Chemically Modified Banana Fibers for the Sorption of Oil from Aqueous Solution, WARP, Vol. 2014, p 2-5.
     Google Scholar
  15. Abdul Hamid, N. S., Malek, N. A. C., Mokhtar, H., Mazlan, W. S., Tajuddin, R. M. (2016) Removal of Oil and Grease from Wastewater using Natural, Journal Teknologi (Science and Engineering), Vol.78(5-3), pp. 97-102.
     Google Scholar
  16. Banerjee, S.S. (2006). Treatment of oil spill by sorption technique using fatty acid grafted sawdust, Chemosphere, 200608, 64(6), 1026-1031.
     Google Scholar