پیوندهای مفید
آمار
| تعداد نشریات | 31 |
| تعداد شمارهها | 708 |
| تعداد مقالات | 6,652 |
| تعداد مشاهده مقاله | 9,193,238 |
| تعداد دریافت فایل اصل مقاله | 6,305,993 |
Integrated chemical coagulation with natural base coagulant – electro-proxone process and ultrafiltration membrane for treatment of compost leachate | ||
| Caspian Journal of Environmental Sciences | ||
| دوره 20، شماره 1، فروردین 2022، صفحه 203-216 اصل مقاله (1.08 M) | ||
| نوع مقاله: Research Paper | ||
| شناسه دیجیتال (DOI): 10.22124/cjes.2022.5427 | ||
| نویسندگان | ||
| Babak Tavakoli؛ Omid Alizadeh* ؛ Fatereh Dorosti | ||
| Department of Chemistry and Chemical Engineering, Rasht Branch, Islamic Azad University, Rasht, Iran | ||
| چکیده | ||
| Guilan Province compost leachate was treated utilizing a hybrid process including chemical treatment followed by electro-proxone and ultra filtration (UF). The effects of different parameters including ratio of natural / chemical coagulant (1:5, 1:15, 1:25), pH (5-8), time (10-90 min), ozone dose (10-90 mg L-1), current intensity (50-500 mA), TMP (0.5-3.5 bar) and temperature (20-50 °C) on COD and turbidity removal were investigated. At optimum conditions of the coagulation process (Salvia hispanica mucilage/FeCl3 = 1:15 and pH = 6.5), 36.19 % and 56.9 % removal efficiencies were obtained for COD and turbidity, respectively. Effluent from the chemical treatment went through. Results from the electro-proxone process showed that by increasing the current intensity from 50 to 350 mA, COD removal efficiency reaches form 14 % to 79 %. By changing O3 concentration from 10 mg L-1 to 90 mg L-1, COD reduction increased and reached from 29 % to 84 %. UF reactor was used for final polishment of the treated wastewater at the optimum TMP of about 1.5 bar and pH = 7.5. By increasing the temperature from 20 °C to 40 °C, permeation flux increased from 76.7 Lm-2 h-1 to 104.1 Lm-2 h-1. However, following the increase of the permeation flux, the removal efficiency of COD and turbidity decreased slightly to 54 % and 90 %, respectively. This study showed that the employed hybrid method is capable of treating the hardly biodegradable compost leachate and obtaining the environmental standards. | ||
| کلیدواژهها | ||
| Compost leachate؛ E- proxone؛ Salvia hispanica mucilage؛ Wastewater treatment | ||
| مراجع | ||
|
Abood, AR, Bao, J, Du, J, Zheng, D & Luo, Y 2014, Non-biodegradable landfill leachate treatment by combined process of agitation, coagulation, SBR and filtration. Waste Management, 34: 439-447.
Adewuyi, A & Adewumi, J 2018, Optimization of Coagulation-Flocculation Process for the Treatment of Wastewater Using Inorganic and Three Natural Coagulants. Futa Journal of Engineering and Engineering Technology, 12: 260-265.
Alavijeh, H, Sadeghi, M, Rajaeieh, M, Moheb, A & Sadani, M 2017, Integrated Ultrafiltration Membranes and Chemical Coagulation for Treatment of Baker’s Yeast Wastewater. Journal of Membrane Science and Technology, 7: 2.
Al-Hamadani, YA, Yusoff, MS, Umar, M, Bashir, MJ & Adlan, MN 2011, Application of psyllium husk as coagulant and coagulant aid in semi-aerobic landfill leachate treatment. Journal of Hazardous Materials, 190: 582-587.
Amor, C, De Torres-Socías, E, Peres, JA, Maldonado, MI, Oller, I, Malato, S & Lucas, MS 2015, Mature landfill leachate treatment by coagulation/flocculation combined with Fenton and solar photo-Fenton processes. Journal of Hazardous Materials, 286: 261-268.
Amr, SSA & Aziz, HA 2012, New treatment of stabilized leachate by ozone/Fenton in the advanced oxidation process. Waste Management, 32: 1693-1698.
Awang, NA & Aziz, HA 2012, Hibiscus rosa-sinensis leaf extract as coagulant aid in leachate treatment. Applied Water Science, 2: 293-298.
Aziz, H, Yii, Y, Syed Zainal, S, Ramli, S & Akinbile, C 2018, Effects of using Tamarindus indica Seeds as a natural coagulant aid in landfill leachate treatment. Global NEST Journal, 20: 373-380.
Bakheet, B, Yuan, S, Li, Z, Wang, H, Zuo, J, Komarneni, S & Wang, Y 2013, Electro-peroxone treatment of Orange II dye wastewater. Water Research, 47: 6234-6243.
Barrera-Díaz, C, Cañizares, P, Fernández, F, Natividad, R & Rodrigo, M 2014, Electrochemical advanced oxidation processes: an overview of the current applications to actual industrial effluents. Journal of the Mexican chemical society, 58: 256-275.
Bohdziewicz, J, Bodzek, M & Górska, J 2001, Application of pressure-driven membrane techniques to biological treatment of landfill leachate. Process Biochemistry, 36: 641-646.
Brillas, E, Calpe, JC & Casado, J 2000, Mineralization of 2, 4-D by advanced electrochemical oxidation processes. Water Research, 34: 2253-2262.
Chaibakhsh, N, Ahmadi, N & Zanjanchi, MA 2014, Use of Plantago major L. as a natural coagulant for optimized decolorization of dye-containing wastewater. Industrial Crops and Products, 61: 169-175.
Chen, J, Zhang, M, Wang, A, Lin, H, Hong, H & Lu, X 2012, Osmotic pressure effect on membrane fouling in a submerged anaerobic membrane bioreactor and its experimental verification. Bioresource Technology, 125: 97-101.
Cortez, S, Teixeira, P, Oliveira, R & Mota, M 2010, Ozonation as polishing treatment of mature landfill leachate. Journal of Hazardous Materials, 182: 730-734.
Cui, YH, Xue, WJ, Yang, SQ, Tu, JL, Guo, XL & Liu, ZQ 2018, Electrochemical/peroxydisulfate/Fe3+ treatment of landfill leachate nanofiltration concentrate after ultrafiltration. Chemical Engineering Journal, 353: 208-217.
Curcio, E, Ji, X, Di Profio, G, Fontananova, E & Drioli, E 2010, Membrane distillation operated at high seawater concentration factors: Role of the membrane on CaCO3 scaling in presence of humic acid. Journal of Membrane Science, 346: 263-269.
Cussler, EL & Cussler, EL 2009, Diffusion: Mass transfer in fluid systems, Cambridge university press.
Deng, Y & Englehardt, JD 2007, Electrochemical oxidation for landfill leachate treatment. Waste Management, 27: 380-388.
Di Palma, L, Ferrantelli, P, Merli, C & Petrucci, E 2002, Treatment of industrial landfill leachate by means of evaporation and reverse osmosis. Waste Management, 22: 951-955.
Dolar, D, Košutić, K & Strmecky, T 2016, Hybrid processes for treatment of landfill leachate: Coagulation/UF/NF-RO and adsorption/UF/NF-RO. Separation and Purification Technology, 168: 39-46.
Freitas, T, Oliveira, V, De Souza, M, Geraldino, H, Almeida, V, Fávaro, S & Garcia, J 2015, Optimization of coagulation-flocculation process for treatment of industrial textile wastewater using okra (A. esculentus) mucilage as natural coagulant. Industrial Crops and Products, 76: 538-544.
Hasar, H, Unsal, SA, Ipek, U, Karatas, S, Cınar, O, Yaman, C & Kınacı, C 2009, Stripping/flocculation/membrane bioreactor/reverse osmosis treatment of municipal landfill leachate. Journal of Hazardous Materials, 171: 309-317.
Hoek, EM & Elimelech, M 2003, Cake-enhanced concentration polarization: A new fouling mechanism for salt-rejecting membranes. Environmental Science & Technology, 37: 5581-5588.
Hua, F, Tsang, YF, Wang, Y, Chan, S, Chua, H & Sin, S 2007, Performance study of ceramic microfiltration membrane for oily wastewater treatment. Chemical Engineering Journal, 128: 169-175.
Im, JH, Woo, HJ, Choi, MW, Han, KB & Kim, CW 2001, Simultaneous organic and nitrogen removal from municipal landfill leachate using an anaerobic-aerobic system. Water Research, 35: 2403-2410.
Ishak, AR, Hamid, FS, Mohamad, S & Tay, KS 2018, Stabilized landfill leachate treatment by coagulation-flocculation coupled with UV-based sulfate radical oxidation process. Waste Management, 76: 575-581.
Jaafarzadeh, N, Barzegar, G & Ghanbari, F 2017, Photo assisted electro-peroxone to degrade 2, 4-D herbicide: The effects of supporting electrolytes and determining mechanism. Process Safety and Environmental Protection, 111: 520-528.
Judd, S 2010, The MBR book: Principles and applications of membrane bioreactors for water and wastewater treatment, Elsevier.
Kennedy, K & Lentz, E 2000, Treatment of landfill leachate using sequencing batch and continuous flow upflow anaerobic sludge blanket (UASB) reactors. Water Research, 34: 3640-3656.
Kishimoto, N, Morita, Y, Tsuno, H, Oomura, T & Mizutani, H 2005, Advanced oxidation effect of ozonation combined with electrolysis. Water Research, 39: 4661-4672.
Kishimoto, N, Nakagawa, T, Okada, H & Mizutani, H 2011, Effect of separation of ozonation and electrolysis on effective use of ozone in ozone-electrolysis process. Ozone: Science & Engineering, 33: 463-469.
Kurniawan, TA, Lo, WH & Chan, GY 2006, Physico-chemical treatments for removal of recalcitrant contaminants from landfill leachate. Journal of Hazardous Materials, 129: 80-100.
Laitinen, N, Luonsi, A & Vilen, J 2006, Landfill leachate treatment with sequencing batch reactor and membrane bioreactor. Desalination, 191: 86-91.
Li, W, Hua, T, Zhou, Q, Zhang, S & Li, F 2010, Treatment of stabilized landfill leachate by the combined process of coagulation/flocculation and powder activated carbon adsorption. Desalination, 264: 56-62.
Li, X, Wang, Y, Zhao, J, Wang, H, Wang, B, Huang, J, Deng, S & Yu, G 2015, Electro-peroxone treatment of the antidepressant venlafaxine: Operational parameters and mechanism. Journal of Hazardous Materials, 300: 298-306.
Li, Z, Yuan, S, Qiu, C, Wang, Y, Pan, X, Wang, J, Wang, C & Zuo, J 2013, Effective degradation of refractory organic pollutants in landfill leachate by electro-peroxone treatment. Electrochimica Acta, 102: 174-182.
Lin, SH & Chang, CC 2000, Treatment of landfill leachate by combined electro-Fenton oxidation and sequencing batch reactor method. Water Research, 34: 4243-4249.
Lin, Z, Yao, W, Wang, Y, Yu, G, Deng, S, Huang, J & Wang, B 2016, Perchlorate formation during the electro-peroxone treatment of chloride-containing water: Effects of operational parameters and control strategies. Water Research, 88: 691-702.
Liu, X, Li, XM, Yang, Q, Yue, X, Shen, TT, Zheng, W, Luo, K, Sun, YH & Zeng, GM 2012, Landfill leachate pretreatment by coagulation–flocculation process using iron-based coagulants: Optimization by response surface methodology. Chemical Engineering Journal, 200: 39-51.
Mokhtarani, N, Bayatfard, A & Mokhtarani, B 2012, Full scale performance of compost’s leachate treatment by biological anaerobic reactors. Waste Management & Research, 30: 524-529.
Mulder, M 2012, Basic principles of membrane technology, Springer Science & Business Media.
Nithya, M & Abirami, M 2018, The leachate treatment by using natural coagulants (pine bark and chitosan). International Research Journal of Engineering and Technology, 5: 2711-2714.
Norouzbahari, S, Roostaazad, R & Hesampour, M 2009, Crude oil desalter effluent treatment by a hybrid UF/RO membrane separation process. Desalination, 238: 174-182.
Patel, H & Vashi, R 2012, Removal of Congo Red dye from its aqueous solution using natural coagulants. Journal of Saudi Chemical Society, 16: 131-136.
Pirbazari, M, Ravindran, V, Badriyha, BN & Kim, SH 1996, Hybrid membrane filtration process for leachate treatment. Water Research, 30: 2691-2706.
Rasool, MA, Tavakoli, B, Chaibakhsh, N, Pendashteh, AR & Mirroshandel, AS 2016, Use of a plant-based coagulant in coagulation-ozonation combined treatment of leachate from a waste dumping site. Ecological Engineering, 90: 431-437.
Renou, S, Poulain, S, Givaudan, J & Moulin, P 2009, Amelioration of ultrafiltration process by lime treatment: Case of landfill leachate. Desalination, 249: 72-82.
Rice, EW, Baird, RB, Eaton, AD & Clesceri, LS 2012, Standard methods for the examination of water and wastewater, American Public Health Association, Washington DC.
Rui, LM, Daud, Z & Latif, AAA 2012, Treatment of leachate by coagulation-flocculation using different coagulants and polymer: A review. International Journal on Advanced Science, Engineering and Information Technology, 2: 114-117.
Salahi, A, Mohammadi, T, Rahmat Pour, A & Rekabdar, F 2009, Oily wastewater treatment using ultrafiltration. Desalination and Water Treatment, 6: 289-298.
Shamsnejati, S, Chaibakhsh, N, Pendashteh, AR & Hayeripour, S 2015, Mucilaginous seed of Ocimum basilicum as a natural coagulant for textile wastewater treatment. Industrial Crops and Products, 69: 40-47.
Shan, TC, Al Matar, M, Makky, EA & Ali, EN 2017, The use of Moringa oleifera seed as a natural coagulant for wastewater treatment and heavy metals removal. Applied Water Science, 7: 1369-1376.
Shu, Z, Lü, Y, Huang, J & Zhang, W 2016, Treatment of compost leachate by the combination of coagulation and membrane process. Chinese Journal of Chemical Engineering, 24: 1369-1374.
Smaoui, Y, Chaabouni, M, Sayadi, S & Bouzid, J 2016, Coagulation–flocculation process for landfill leachate pretreatment and optimization with response surface methodology. Desalination and Water Treatment, 57: 14488-14495.
Smaoui, Y, Mseddi, S, Ayadi, N, Sayadi, S & Bouzid, J 2019, Evaluation of influence of coagulation/flocculation and fenton oxidation with iron on landfill leachate treatment. Environment Protection Engineering, 45.
Šostar-Turk, S, Petrinić, I & Simonič, M 2005, Laundry wastewater treatment using coagulation and membrane filtration, Resources. Conservation and Recycling, 44: 185-196.
Stamatialis, D, Stafie, N, Buadu, K, Hempenius, M & Wessling, M 2006, Observations on the permeation performance of solvent resistant nanofiltration membranes. Journal of Membrane Science, 279: 424-433.
Subramonian, W, Wu, TY & Chai, SP 2014, A comprehensive study on coagulant performance and floc characterization of natural Cassia obtusifolia seed gum in treatment of raw pulp and paper mill effluent. Industrial Crops and Products, 61: 317-324.
Tawakkoly, B, Alizadehdakhel, A & Dorosti, F 2019, Evaluation of COD and turbidity removal from compost leachate wastewater using Salvia hispanica as a natural coagulant. Industrial Crops and Products, 137: 323-331.
Wang, H, Yuan, S, Zhan, J, Wang, Y, Yu, G, Deng, S, Huang, J & Wang, B 2015, Mechanisms of enhanced total organic carbon elimination from oxalic acid solutions by electro-peroxone process. Water Research, 80: 20-29.
Wang, H, Zhan, J, Yao, W, Wang, B, Deng, S, Huang, J, Yu, G & Wang, Y 2018, Comparison of pharmaceutical abatement in various water matrices by conventional ozonation, peroxone (O3/H2O2), and an electro-peroxone process. Water Research, 130: 127-138.
Wang, Y, Li, X, Zhen, L, Zhang, H, Zhang, Y & Wang, C 2012, Electro-Fenton treatment of concentrates generated in nanofiltration of biologically pretreated landfill leachate. Journal of Hazardous Materials, 229: 115-121.
Wang, Y, Yu, G, Deng, S, Huang, J & Wang, B 2018, The electro-peroxone process for the abatement of emerging contaminants: Mechanisms, recent advances, and prospects. Chemosphere, 208: 640-654
Yoo, HC, Cho, SH & Ko, SO 2001, Modification of coagulation and Fenton oxidation processes for cost-effective leachate treatment. Journal of Environmental Science and Health, Part A, 36: 39-48.
Zhang, H, Wang, Z, Liu, C, Guo, Y, Shan, N, Meng, C & Sun, L 2014, Removal of COD from landfill leachate by an electro/Fe2+/peroxydisulfate process. Chemical Engineering Journal, 250: 76-82.
Zheng, HS, Guo, WQ, Wu, QL, Ren, NQ & Chang, JS 2018, Electro-peroxone pretreatment for enhanced simulated hospital wastewater treatment and antibiotic resistance genes reduction. Environment International, 115: 70-78.
| ||
|
آمار تعداد مشاهده مقاله: 976 تعداد دریافت فایل اصل مقاله: 1,281 |
||