Substrate Modification and Magnetic Water Treatment on the Maintenance of Tunnel Drainage Systems. I: Feasibility Tests
Publication: Journal of Performance of Constructed Facilities
Volume 29, Issue 3
Abstract
Calcium carbonate deposits are known to clog tunnel drainage systems and clogging is a major concern to tunnel operators worldwide. After analyzing several industrial solutions for treating calcium carbonate, experiments were conducted to evaluate the use of substrate modification and magnetic fields in inhibiting calcium carbonate deposition. For substrate modification tests, laboratory experiments showed the least amount of deposits on polytetrafluoroethylene and polydimethylsiloxane coatings, while polyvinyl chloride (PVC) pipes showed the most. Simulated tunnel drainage test results showed PVC pipes inclined at large gradients and PVC pipes with installed magnets to have slightly less calcite deposits than PVC pipes without magnets. The amount of deposits suggested the influence of magnetic fields to be minor and secondary relative to water velocity.
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Acknowledgments
This work was financially supported by the Seoul R&BD Program (No. ST100052). Special thanks go to Jonghwi Lee, Ikchan Ju, Jungwu Nam, Eunhyeong Park, and Saehwan Yun for their help in conducting experiments and communications.
References
Alimi, F., Tlili, M. M., Ben Amor, M., Maurin, G., and Gabrielli, C. (2009). “Effect of magnetic water treatment on calcium carbonate precipitation: Influence of the pipe material.” Chem. Eng. Process., 48(8), 1327–1332.
Andritsos, N., Karabelas, A. J., and Koutsoukos, P. G. (1997). “Morphology and structure of scale layers formed under isothermal flow conditions.” Langmuir, 13(10), 2873–2879.
Baker, J. S., and Judd, S. J. (1996). “Magnetic amelioration of scale formation.” Water Res., 30(2), 247–260.
Ben Amor, M., Zgolli, D., Tlili, M. M., and Manzola, A. S. (2004). “Influence of water hardness, substrate nature and temperature on heterogeneous calcium carbonate nucleation.” Desalination, 166, 79–84.
Bobet, A. (2003). “Effect of pore water pressure on tunnel support during static and seismic loading.” Tunnelling Underground Space Technol., 18(4), 377–393.
Chibowski, E., Holysz, L., and Szcześ, A. (2003). “Adhesion of in situ precipitated calcium carbonate in the presence and absence of magnetic field in quiescent conditions of different solid surfaces.” Water Res., 37(19), 4685–4692.
Fathi, A., Mohamed, T., Gabrielli, C., Maurin, G., and Mohamed, B. A. (2006). “Effect of magnetic water treatment on homogenous and heterogeneous precipitation of calcium carbonate.” Water Res., 40(10), 1941–1950.
Gabrielli, C., Jaouhari, R., Maurin, G., and Keddam, M. (2001). “Magnetic water treatment for scale prevention.” Water Res., 35(13), 3249–3259.
Gamisch, T., and Girmscheid, G. (2005). “Application of an innovative green-chemistry product onto drainage systems in traffic tunnels for life-cycle oriented optimization of maintenance management.” Proc., 3rd Int. Struct. Eng. Constrcut. Conf., Australian Underground Construction and Tunneling Association, Shunan, Japan, 769–777.
Gehr, R., Zhai, Z. A., Finch, J. A., and Ram Rao, S. (1995). “Reduction of soluble mineral concentrations in saturated water using magnetic field.” Water Res., 29(3), 933–940.
Han, T. Y.-J., and Aizenberg, J. (2008). “Calcium carbonate storage in amorphous form and its template-induced crystallization.” Chem. Mater., 20(3), 1064–1068.
Harms, W. D., Jr., and Bruce Robinson, R. (1992). “Softening by fluidized bed crystallizers.” J. Environ. Eng., 513–529.
Higashitani, K., Kage, A., Katamura, S., Imai, K., and Hatade, S. (1993). “Effects of a magnetic field on the formation of particles.” J. Colloid Interface Sci., 156(1), 90–95.
Knez, S., and Pohar, C. (2005). “The magnetic field influence on the polymorph composition of precipitated from carbonized aqueous solutions.” J. Colloid Interface Sci., 281(2), 377–388.
Krauter, P. W., Harrar, J. E., Orloff, S. P., and Bahowick, S. M. (1996). “Test of a magnetic device for amelioration of scale formation at treatment facility D.”, Lawrence Livermore National Laboratory, Livermore, CA.
Li, X., Zhang, J., and Yang, D. (2012). “Determination of antiscaling efficiency and dissolution capacity for calcium carbonate with ultrasonic irradiation.” Ind. Eng. Chem. Res., 51(27), 9266–9274.
Limpert, G. J. C., and Raber, J. L. (1985). “Tests of nonchemical scale control devices in a once-through system.” Mater. Performance, 24(10), 40–45.
Martinod, A., Euvrard, M., Foissy, A., and Neville, A. (2008). “Progressing the understanding of chemical inhibition of mineral scale by green inhibitors.” Desalination, 220(1–3), 345–352.
Ogino, T., Suzuki, T., and Sawada, K. (1987). “The formation and transformation mechanism of calcium carbonate in water.” Geochim. Cosmochim. Acta, 51(10), 2757–2767.
Ogino, T., Suzuki, T., and Sawada, K. (1990). “The rate and mechanism of polymorphic transformation of calcium carbonate in water.” J. Cryst. Growth, 100(1–2), 159–167.
Oren, Y. (2008). “Capacitive deionization (CDI) for desalination and water treatment—Past, present and future (a review).” Desalination, 228(1–3), 10–29.
Patton, C. C. (2007). Applied water technology, John M. Campbell, Norman, OK.
Rautenbach, R., Offermann, H., and Hammer, E. E. (1983). “An assessment of different scale control methods.” Desalination, 47(1–3), 49–62.
Setta, F.-A., and Neville, A. (2011). “Efficiency assessment of inhibitors on precipitation kinetics in the bulk and deposition on a stainless steel surface (316 L).” Desalination, 281, 340–347.
Shin, J. H., Addenbrooke, T. I., and Potts, D. M. (2002). “A numerical study of the effect of groundwater movement on long-term tunnel behavior.” Géotechnique, 52(6), 391–403.
Smothers, K. W., Curtiss, C. D., Gard, B. T., Strauss, R. H., and Hock, V. F. (2001)., U.S. Army Corps of Engineers, Washington, DC.
Tai, C. Y., Wu, C.-K., and Chang, M.-C. (2008). “Effects of magnetic field on the crystallization of using permanent magnets.” Chem. Eng. Sci., 63(23), 5606–5612.
Tzotzi, Ch., Pahiadaki, T., Yiantsios, S. G., Karabelas, A. J., and Andritsos, N. (2007). “A study of scale formation and inhibition in RO and NF membrane processes.” J. Membr. Sci., 296(1–2), 171–184.
Westin, K. J., and Rasmuson, A. C. (2005). “Crystal growth of aragonite and calcite in presence of citric acid, DTPA, EDTA and pyromellitic acid.” J. Colloid Interface Sci., 282(2), 359–369.
Yee, E., Lee, J. H., Lim, D. S., and Chun, B. S. (2012). “Magnetic water treatment to inhibit calcium carbonate scale deposition in the drainage system of an old tunnel in Seoul, South Korea.” Adv. Mater. Res., 594–597, 2045–2055.
Zeppenfeld, K. (2011). “Electrochemical removal of calcium and magnesium ions from aqueous solutions.” Desalination, 277(1–3), 99–105.
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© 2014 American Society of Civil Engineers.
History
Received: Mar 21, 2013
Accepted: Dec 26, 2013
Published online: Aug 12, 2014
Discussion open until: Jan 12, 2015
Published in print: Jun 1, 2015
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