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Magnetic treatment of industrial water. Silica activation

Published online by Cambridge University Press:  15 April 2002

A. Szkatula ,
M. Balanda  and
M. Kopeć
A. Szkatula
Affiliation:
H. Niewodniczański Institute of Nuclear Physics, Radzikowskiego 152, 31-342 Kraków, Poland
M. Balanda*
Affiliation:
H. Niewodniczański Institute of Nuclear Physics, Radzikowskiego 152, 31-342 Kraków, Poland
M. Kopeć
Affiliation:
H. Niewodniczański Institute of Nuclear Physics, Radzikowskiego 152, 31-342 Kraków, Poland
*
[email protected]
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Abstract

The paper presents two large-scale observations of magnetic treatment of industrial water, aimed at investigating changes in the formation of deposits. First, a four-month experiment is described with two identical 25 kW heat exchangers, where in one case the inlet water was treated by a magneto-hydrodynamic method. Deposits recovered from both exchangers were analyzed chemically, by X-ray diffraction, infrared spectroscopy and PIXE. The amount of deposit for untreated water, composed mostly of calcite, increased exponentially with temperature reaching 20 g/m of tube at the warm end of the heat exchanger. The mass of the deposit for magnetically treated water did not depend on temperature and was only ca. 0.5 g/m of tube. It was composed of mainly noncrystalline silica-rich material. Further results were obtained from the practical installation at three blocks of a 1 GW power plant. The soft, amorphous deposit for magnetically treated water had a specific surface area of 80 m2/g and an infrared spectrum similar to that of a silicate hydrogel. Therefore, it appeared that, as a result of the passage through the magnetic device, crystallization of carbonates in water was blocked due to initiation of another, competitive process. This process is the activation of the colloidal silica, which will adsorb calcium, magnesium or other metal ions and then precipitate from the solution as the coagulated agglomerate. The most probable mechanism responsible for silica activation is a Lorentz-force induced deformation of the diffuse layer leading to the increased counterion concentration in the adsorption layer of the negatively charged silica.

Keywords

Type
Research Article
Information
The European Physical Journal - Applied Physics , Volume 18 , Issue 1 , April 2002 , pp. 41 - 49
Copyright
© EDP Sciences, 2002

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References

Vermeiren, Th., Corrosion Technol. 5, 215 (1958).
Klassen, V.I., Dokl. Akad. Nauk SU 166, 1383 (1966); Omagnicivanije vodnych sistem (in Russian) (Ed. Chimija, Moskva, 1978); in Developments in Mineral Processing (Elsevier, N.Y., 1981), Part B, Mineral Processing, p. 1077.
Kronenberg, K.J., IEEE Trans. Magn. 21, 2059 (1985). CrossRef
E.F. Tebenihin, B.T. Gusev, Obrabotka vody magnitnym polem v teploenergetike (Ed. Energija, 1970).
Kruglitskij, N.N., Kataev, G.A., Zhantalay, B.P., Rubezhanskij, K.A., Kolomec, A.A., Kolloid. Zh. 47, 493 (1985).
Parsons, S.A., Wang, B.L., Udol, S., Judd, S.J., Stephenson, T., Trans. IChemE (part B) 74, 98 (1997). CrossRef
Lin, I.J., Yotvat, J., J. Magn. Magn. Mater. 83, 525 (1990). CrossRef
Levic, V.G., Uspekhi Fiz. Nauk 88, 787 (1966) (in Russian). CrossRef
Krylov, O.T., Vikulova, I.K., Eletsky, V.V., Rozno, N.A., Klassen, V.I., Coll. J. USRR 47, 31 (1985).
Higashitani, K., Okuhara, K., Hatade, S., J. Colloid Interface Sci. 152, 125 (1992). CrossRef
Higashitani, K., Iseri, H., Okuhara, K., Kage, A., Hatade, S., J. Colloid Interface Sci. 172, 383 (1995). CrossRef
Higashitani, K., Oshitani, J., J. Colloid Interface Sci. 204, 363 (1998). CrossRef
Oshitani, J., Uehara, R., Higshitani, K., J. Colloid Interface Sci. 209, 374 (1999). CrossRef
Anti-scale Magnetic Treatment and Physical Conditioning, Proc. MAG 3 (Ed. S. Parsons, Cranfield University, 1999), ISBN - 1 86194 010 6.
Coey, J.M.D., Cass, S., J. Magn. Magn. Mater. 209, 71 (2000). CrossRef
Lipus, L.C., Krope, J., Crepinsek, L., J. Colloid Interface Sci. 236, 60 (2001). CrossRef
V.C. Farmer, The Infrared Spectra of Minerals (Mineralogical Society Monograph 4, London, 1974).
W. Eitel, The Physical Chemistry of the Silicates (The University of Chicago Press, 1954).
A. Szkatula et al., Magnetohydrodynamic method of water treatment, European Patent No. 0241 090 B1, Cl. C02F 1/48.
A. Szkatula et al., in preparation.
Kitamura, M., J. Colloid Interface Sci. 236, 318 (2001). CrossRef
Colic, M., Morse, D., Langumir 14, 783 (1998). CrossRef
R.K. Iler, The Chemistry of Silica (Wiley, New York, 1979).
L.A. Kulskii, Theoretical Bases and Technology of Water Conditioning (Ed. Naukova Dumka, Kiev, 1980) (in Russian).
M. Smoluchowski, Phys. Zeit. XVII, 557-571; 587-599 (1916).
Gamayunov, N.I., Kolloid. Zh. 56, 290 (1994); English Translation: Colloid. J. 56, 234 (1994).
R.J. Hunter, Introduction to Modern Colloidal Science (Oxford Science Publications, New York, 1996).
Du, Q., Freysz, E., Shen, Y.R., Phys. Rev. Lett. 72, 238 (1994). CrossRef
Yaminsky, V.V., Ninham, B.W., Pashley, R.M., Langumir 14, 3223 (1998). CrossRef