To assess the effects of magnetic water treatment under well controlled laboratory conditions, and to yield statistically defensible results, a saturated solution of CaSO4 · 2H2O was tested in the magnetic field of a nuclear magnetic resonance spectrometer. Five replicates were performed of each experiment. The two independent variables tested-magnetic field strength and rotation speed—were set at two levels, “on” (4.75 T and 1200 rpm respectively) or “off”. Parameters chosen to monitor the treatment effect were conductivity, soluble calcium, total suspended solids (TSS), and Zeta potential (ζ). Results showed that the magnetic treatment indeed had a significant effect on the precipitation of CaSO4 crystals. Conductivity, soluble Ca, and ζ potential all decreased, whereas TSS increased. A transfer of Ca from the soluble to the solid phase (crystal as CaSO4 · 2H2O) was confirmed by mass balance calculations. Thus the results are consistent with claims in the literature that magnetic water treatment can induce precipitation of inorganic crystals from solution, and could possibly prevent scaling by avoiding precipitation of these salts on to solid surfaces.
[1]
D. Hasson,et al.
Effectiveness of magnetic water treatment in suppressing calcium carbonate scale deposition
,
1985
.
[2]
Larry M. McGaughey,et al.
Prediction of the calcium carbonate saturation pH in cooling water
,
1980
.
[3]
A. Brosh,et al.
A note on the effect of magnetically treated drinking water on the performance of fattening cattle
,
1992
.
[4]
I. Lin,et al.
Exposure of irrigation and drinking water to a magnetic field with controlled power and direction
,
1990
.
[5]
B. Q. Welder,et al.
Practical Performance of Water-Conditioning Gadgets
,
1954
.
[6]
Garrison Sposito,et al.
The surface chemistry of soils
,
1984
.
[7]
I. M. Glushchenko,et al.
Magnetic apparatus for the coke and chemical industry
,
1983
.