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Wastewater Treatment by Effluent Treatment Plants

International Journal of Civil Engineering
© 2016 by SSRG - IJCE Journal
Volume 3 Issue 12
Year of Publication : 2016
Authors : Rakesh Singh Asiwal, Dr. Santosh Kumar Sar, Shweta Singh, Megha Sahu
10.14445/23488352/IJCE-V3I12P105
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How to Cite?

Rakesh Singh Asiwal, Dr. Santosh Kumar Sar, Shweta Singh, Megha Sahu, "Wastewater Treatment by Effluent Treatment Plants," SSRG International Journal of Civil Engineering, vol. 3,  no. 12, pp. 29-35, 2016. Crossref, https://doi.org/10.14445/23488352/IJCE-V3I12P105

Abstract:

Most of the river basins are closing or closed to severe water shortages, brought on by the simultaneous effects of agricultural growth, industrialization and urbanization. Performance of state owned sewage treatment plants, for treating municipal waste water, and common effluent treatment plants, for treating effluent from small scale industries, is also not complying with prescribed standards. Thus, effluent from the treatment plants, often, not suitable for household purpose and reuse of the waste water is mostly restricted to agricultural and industrial purposes. The development of innovative technologies for treatment of wastewaters from various industries is a matter of alarming concern for us. Although many research papers have been reported on wastewater pollution control studies, but a very few research work is carried out for treatment of wastewater of steel industries, especially in reference to development of design of industrial effluent Treatment Plants (ETP) system. Another beneficial aspect of this research work will be recycling, reuse of water and sludge from steel industry The whole technologies for treating industrial wastewater can be divided into four categories: - Chemical, Physical, Biological and mathematical approaches.

Keywords:

 

Waste water, Effluent treatment plants (ETP), Environmental Impact assessment (EIA), and Physical treatment.

References:

1. Dean J. G., F. L. Basqui and Lanouette, 1972, Removing heavy metals from wastewater Env. Sci. Tech. 6:518
2. Huang C. P. 1977, Removal of heavy metals from industrial effluents J. Env . Eng. Division, ASCE 118 (EE6): 923-947.
3. Loomba, K. and G. S. Pandey 1993, Selective removal of some toxic metals ions (Hg(II), pb (II) and Zn(II)) by reduction using steel plants granulated slag. Indian J. Env., Health A:20:105-112.
4. Shrivastava, A.K., A Review on copper pollution and its removal from water bodies by pollution control Technologies, IJEP 29(6): 552-560, 2009.
5. Journal of environmental Management, vol. 88, issue 3, August 2008, pp. 437-447.
6. Industrial wastewater reuses potential – internet (web) 7. Waste Management Strategies for industries.
8. U.S. Environmental protection Agency, Design criteria for Mechanical, Electric and Fluid system and Washington, D. C.,1974.
9. Raj kumar Agrawal and Piyush Kant Pandey, Productive recycling of basic oxygen furnace sludge in integrated steel plant. Journal of scientific and industrial Research, vol. 64, sept. 2005, pp. 702-706.
10. B. Das, S. Prakash, P.S.R. Reddy, VN Mishra, An overview of utilization of slag and sludge from steel industries, Resources, Conservation and Recycling Vol. 50, Issue1, March 2007, pp. 40-57.
11. Richard D. Hook, Steel Mill Sludge Recovery, Journal. Water pollution control Federation, vol.33, No. 10 (Oct. 1961) pp.1.
12. P. K. Bhunia, M. K. Stenstrom, optimal design and operation of wastewater treatment plant, 1986. [20] Ulf Jeppson, Modeling aspects of wastewater treatment process,
13. M. Drolka et al ., model and wastewater treatment, chem.. Biochem Eng. Q.15 (2) pp. 71-74 (2001) [22] JPN Rai et al ., mathematical model for phytoremediation of pulp and paper industries wastewater, JSIR, 64, 2005,PP 717-721.
14. A. O. Ibeje, B. C. Okoro, mathematical modeling of cassava wastewater treatment using anaerobic Baffled Reactor, AJER, 2(5).2013,pp. 128-134.
15. Alqahtani, R., Nelson, M. I. & Worthy, A. L., A mathematical Model for the biological treatment of industrial wastewater in a reactor cascade. CHEMECA 2011(pp. 1-11).
16. L. D. Robescu et. al., Mathematical modeling of Sharon Biological Wastewater treatment Process, U. P. B. Sci. Bull. Series D, 74(1), 2102, pp. 229-236.
17. Anonymous. 2004. NATP – MM project report on ‘Use of Urban and Industrial Effluent in Agriculture’ CSSRI, Karnal 132001, India.
18. Bhamoriya V. 2004. Wastewater Irrigation in Vadodara, Gujarat, India: Economic Catalyst for Marginalized Communities. In: Scott CA, Faruqui NI and Raschid-Sally L. (Eds). Wastewater Use in Irrigated Agriculture: Confronting Livelihhod and Environmental Realities. CAB International in Association with IWMI: Colmbo, Sri Lanka, and IDRC: Ottawa, Canada.
19. Bhardwaj RM. 2005. Status of Wastewater Generation and Treatment in India, IWG-Env Joint Work Session on Water Statistics, Vienna, 20-22 June 2005.
20. Billore, S.K., Singh, N., Sharma, J.K.,Nelson, R.M., Dass, P. (1999). Horizontal subsurface flow gravel bed contructed wetland with Phragmites karka in Central India. Water Science and Technology. 40: 163-171.
21. Billore, S.K., Singh, N., Ram, H.K., Sharma, J.K., Singh, V.P., Nelson, R.M., Dass, P. (2001). Treatment of molasses based distillery effluent in a contructed wetland in Central India. Water Science Technology. 44: 441-448.
22. Billore, S.K., Ram, H., Singh, N., Thomas, R., Nelson, R.M., Pare, B. (2002). Treatment performance evaluation of surfactant removal from domestic wastewater in a tropical horizontal subsurface constructed wetland. In: Proceedings of the 8th International Conference on Wetland Systems for Water Pollution Control, University of Dar-es-Salaam, Tanzania and IWA, pp. 393- 399.