Evaluation of the Efficiency of Integrated Fixed-Film Activated Sludge reactor for Treatment of Wastewater from Vegetable Oil Industries

Monazami Tehrani, Ghazaleh; Molla Mahmoudi, Mohammad; Borgheipour, Hasti; Nezampour, Alireza

doi:10.29252/ArchHygSci.7.3.192

Volume 7, Issue 3 (Summer 2018) Arch Hyg Sci 2018, 7(3): 192-199 | Back to browse issues page

‎ 10.29252/ArchHygSci.7.3.192

‎ 20.1001.1.22519203.2018.7.3.7.4

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Monazami Tehrani G, Molla Mahmoudi M, Borgheipour H, Nezampour A. Evaluation of the Efficiency of Integrated Fixed-Film Activated Sludge reactor for Treatment of Wastewater from Vegetable Oil Industries . Arch Hyg Sci 2018; 7 (3) :192-199
URL: http://jhygiene.muq.ac.ir/article-1-323-en.html

Evaluation of the Efficiency of Integrated Fixed-Film Activated Sludge reactor for Treatment of Wastewater from Vegetable Oil Industries

Ghazaleh Monazami Tehrani¹

, Mohammad Molla Mahmoudi²

, Hasti Borgheipour ^*

³, Alireza Nezampour⁴

1- Department of Health, Safety and Environment, school of public health and safety, Shahid Beheshti University of Medical Scien ces and Health Services
2- Department of Environmental Health Engineering, School of Public Health, Hamadan University of Medical Sciences,
3- Department of Environmental Engineering, Central Tehran Branch, Islamic Azad University
4- D epartment of Health, Safety, and Environment, S chool of Engineering, Islamic Azad University, Central Tehran Branch

Abstract: (4686 Views)

Background & Aims of the Study: Wastewater discharges from vegetable oil industry cause environmental problem, including pollution of groundwater and surface water. Therefore, this study evaluated the efficiency of Integrated Fixed-Film Activated Sludge (IFAS) reactor for treatment of wastewater from Varamin vegetable oil industries.
Materials & Methods: This was an experimental study. The anaerobic reactor and the aerobic reactor with sedimentation unit were made from polyethylene and plexiglas. The IFAS reactor was packed with ratio 70% by Honeycomb packing F 19-1. To create optimal growth conditions for microorganisms in anaerobic digestion, the COD/N/P ratio was adjusted to 300/5/1. Sampling and analysis of the total of the parameters studied at the system stability time during different times from the pilot output.
Results: The results showed the high removal efficiency of the COD, BOD and TSS (97.9%, 98.2% and 98.8 %, for 2 day anaerobic and 8 hrs aerobic, respectively). Also, the highest COD removal efficiency was observed for these three parameters in the IFAS system at HRT 8 hrs aerobic (>99.7%, >97.7% and 97.6 %, respectively).

Conclusion: In general, the results showed that industrial wastewater treatment methods using the IFAS biological reactor are a suitable method for the removal of pollutants and can replace conventional methods. Also, the efficiency of removing COD, BOD and TSS from plant effluent has been at the optimum level for all retention time managed by the IFAS system.

Keywords: Integrated Fixed-Film Activated Sludge, Attached Growth, Industrial Wastewater, Vegetable Oil Industry, Biological Treatment.

Full-Text [PDF 572 kb] (875 Downloads) | | Full-Text (HTML) (1008 Views)

Type of Study: Original Article | Subject: Environmental Health
Received: 2018/03/11 | Accepted: 2019/03/27 | Published: 2018/10/7

References

1. Keramati H, Parvaresh A, Movahedian Attar H. Survey of dissolved air flotation (DAF) system efficiency for reduce of pollution of Naz vegetable oil factory's wastewater in Isfahan. Horizon Med Sci. 2006; 12 (3) :33-37.

2. Mohamadi N, Ali Dadolahi S. A Study on the Effects of Food Industry Sewage on the Agricultural Water in Dezful. JEST. 2012;14(4):55-62.

3. Khosravi M, Hassani AH, Khani MR, Yaghmaeian K. Synthetic Analysis of Nitrogen and Phosphorous Removal from Municipal Wastewater Using Sequencing Batch Bio-film Reactor with Fixed Bed. JEST. 2016;17(4):59-73

4. Bajaj M, Gallert C, Winter J. Biodegradation of high phenol containing synthetic wastewater by an aerobic fixed bed reactor. Bioresource Technology. 2008;99(17): 8376–8381.

5. Xin Z, Yanming W, Zhengfang Y. Oil field wastewater treatment in biological aerated filter by immobilized microorganisms. Process Biochemistry. 2006;41(7): 1475-1483.

6. Yen-Hui L. Kinetics of nitrogen and carbon removal in a moving fixed bed biofilm reactor. Applied Mathematical Modeling. 2008;32(11): 2360–2377.

7. Mahendran B, Lishman L, Liss S.N. Structural, physicochemical and microbial properties of flocs and biofilms in integrated fixed-film activated sludge (IFFAS) systems. water research. 2012; 46: 5085-5101.

8. Azimi A.A, Hooshyari B, Hradi N.M, Didendi Gh. Enhanced COD and Nutrienent removal efficiency in a hybrid integrated fixed film activated. Iranian Journal of Science & Technology, Transaction B, Engineering. 2007; 31(B5): 523-533.

9. Borghei S, Sharbatmaleki M, Pourrezaie P, Borghei G. Kinetics of organic removal in fixedbed aerobic biological reactor. Bioresource Technology. 2008;99(5): 1118-1124.

10. APHA. AWWA. WEF. Standard Methods for the Examination of Water and Wastewater”. 20th Ed. Washington APHA. 1998.

11. Li C, Li X. L, Ji M, Liu J. Performance and microbial characteristics of integrated fixed-film activated sludge system treating industrial wastewater. Water Science & Technology. 2012;66(12):2785-2792.

12. Azimi N, Taheriyoun M. The Performance of Integrated Fixed Film Activated Sludge in Wastewater Treatment of Food Industry (Case Study: Amol Industrial Park Wastewater Treatment Plant). J water and wastewater. 2013;24(3)80-87.

13. Regmi P, Thomas W, Schafran G, Bott Ch, Rutherford B, Waltrip D. Nitrogen removal assessment through nitrification rates and media biofilm accumulation in an IFAS process demonstration study. Water Res. 2011;45:6699-6708.

14. Veuillet F, Lacroix S, Bausseron A, Gonidec E, Ochoa J, Christensson M, Lemaire R. Integrated fixed-film activated sludge ANITA™Mox process – a new perspective for advanced nitrogen removal. Water Science & Technology. 2014;69(5): 915-922.

15. Dargahi A, Mohammadi M, Amirian F, Karami A, Almasi A. Phenol removal from oil refinery wastewater using anaerobic stabilization pond modeling and process optimization using response surface methodology (RSM). Desalination and Water Treatment. 2017;87:199-208.