Browse > Article
http://dx.doi.org/10.12989/mwt.2017.8.2.125

Carbonate scale reduction in reverse osmosis membrane by CO2 in wastewater reclamation  

Shahid, Muhammad Kashif (Department of Environmental Engineering, Daegu University)
Pyo, Minsu (Department of Environmental Engineering, Daegu University)
Choi, Young-Gyun (Department of Environmental Engineering, Daegu University)
Publication Information
Membrane and Water Treatment / v.8, no.2, 2017 , pp. 125-136 More about this Journal
Abstract
Reverse osmosis technology is being used on large scale for treatment of ground water, brackish water, wastewater and sea water. The most challenging issue in RO process is carbonate scaling which is directly linked with the efficiency and economy. Considering the natural phenomena of carbonate scaling different adaptations have been made to control scaling on the surface of RO membrane including acid dosage and antiscalant addition. As carbonate scaling is directly related with pH level of feed water, present study describes an experimental approach to reduce scaling on RO membrane by lowering the feed water pH by purging $CO_2$. In this comparative study four different conditions including control process (without any scale inhibitor), with dosage of antiscalant, with purging of $CO_2$ and with co addition of antiscalant and $CO_2$ in a feed stream line; it was established that $CO_2$ is a better appliance to reduce carbonate scaling on the membrane surface by reduce pH of feed stream. It was also observed that $CO_2$ and antiscalant mutually function better for scale control.
Keywords
$CaCO_3$; transmembrane pressure (TMP); RO; membrane fouling; $CO_2$ purging; antiscalant;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
연도 인용수 순위
1 Adriano, J., Claudia, B., Paolo, F., Stephan, K., Martin, K., Christa, S.M., Karin, R., Yuansong, W., Ana, Z. and Hansruedi, S. (2011), "Water reuse: >90% water yield in MBR/RO through concentrate recycling and $CO_2$ addition as scaling control", Water Res., 45, 6141-6151.   DOI
2 American public health association, American water works association, Water environment federation (2012), Standard Methods for the Examination of Water and Wastewater, 22nd Edition, Washington, D.C.
3 Antony, A., Low, J.H., Gray, S., Childress, A.E., Le-Clech, P. and Leslie, G. (2011), "Scale formation and control in high pressure membrane water treatment: A review", J. Membr. Sci., 383, 1-16.   DOI
4 Bartels, C.R., Wilf, M., Andes, K. and Iong, J. (2005), "Design considerations for wastewater treatment by reverse osmosis", Water Sci. Technol., 51, 473-482.   DOI
5 Daniel, J.M., Sirirat, K., Donald, R.P. and Benny, D.F. (2014), "Comparison of membrane fouling at constant flux and constant TMP conditions", J. Membr. Sci., 454, 505-515.   DOI
6 Emmanuelle, F., Jingshi, W., Marc, P., Wolfgang, G. and Zhiguo, Y. (2015), "Biofouling and scaling control of reverse osmosis membrane using one-step cleaning-potential of acidified nitrite solution as an agent", J. Membr. Sci., 495, 276-283.   DOI
7 Fritzmann, C., Lowenberg, J., Wintgens, T. and Melin, T. (2007), "State-of-the-art of reverse osmosis desalination", Desalination, 216, 1-76.   DOI
8 Greenlee, L.F., Lawler, D.F., Freeman, B.D., Marrot, B. and Moulin, P. (2009), "Reverse osmosis desalination: water sources, technology, and today's challenges", Water Res., 43, 2317-2348.   DOI
9 Holloway, R.W., Leslie Miller-Robbie, L., Patel, M., Jennifer, R.S., Junko, M.M., Jason, D. and Tzahi, Y.C. (2016), "Life-cycle assessment of two potable water reuse technologies: MF/RO/UV-AOP treatment and hybrid osmotic membrane bioreactors", J. Membr. Sci., 507, 165-178.   DOI
10 Greenlee, L.F., Testa, F., Lawler, D.F., Freeman, B.D. and Moulin P (2010), "The effect of antiscalant addition on calcium carbonate precipitation for a simplified synthetic brackish water reverse osmosis concentrate", Water Res., 44, 2957-2969.   DOI
11 Lau, W.J., Goh, P.S., Ismail, A.F. and Lai, S.O. (2014), "Ultrafiltration as a pretreatment for seawater desalination: A review", Membr. Water Treat., 5(1), 15-29.   DOI
12 Prihasto, N., Feng, Q.L. and Kim, S.H. (2009), "Pre-treatment strategies for seawater desalination by reverse osmosis system", Desalination, 249, 308-316.   DOI
13 Lee, S., Kim, J. and Lee, C.H., (1999), "Analysis of $CaSO_4$ scale formation mechanism in various nanofiltration modules", J. Membr. Sci., 163, 63-74.   DOI
14 Okazaki, M. and Shoji, K. (1984), "Scale formation on reverse osmosis membranes", J. Chem. Eng. JPN, 17, 145-151.   DOI
15 Pervov, A.G. (1991), "Scale formation prognosis and cleaning procedure schedules in reverse osmosis systems operation", Desalination, 83, 77-118.   DOI
16 Pype, M.L., Michael, G.L., Jurg, K. and Wolfgang, G. (2016), "Reverse osmosis integrity monitoring in water reuse: The challenge to verify virus removal - A review", Water Res., 98, 384-395.   DOI
17 Zhao, Y., Lianfa, S. and Leong, S.O. (2010), "Fouling behavior and foulant characteristics of reverse osmosis membranes for treated secondary effluent reclamation", J. Membr. Sci., 349, 65-74.   DOI
18 Razavi, S.M.R., Miri, T., Barati, A., Nazemian, M. and Sepasi, M. (2015), "Industrial wastewater treatment by using of membrane", Membr. Water Treat., 6(6), 489-499.   DOI
19 Wei, M., Zhao, Y. and Wang, L. (2007), "The pretreatment with enhanced coagulation and a UF membrane for seawater desalination with reverse osmosis", Desalination, 203, 256-259.   DOI
20 Zeiher, E.K., Ho, B. and Williams, K.D. (2003), "Novel antiscalant dosing control", Desalination, 157, 209-216.   DOI