14.5.2: Precipitation of Dissolved Solids

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Dissolved solids are a problem when they precipitate as a solid mineral or serve as a source of nutrients for algae and bacterial slime. Clogging and eventual plugging of water applicators by precipitates and organic deposits are problems that cannot be solved by filtration. Precipitates form inside pipes or emitters as a result of changing pH or temperature, but a major cause of mineral deposits is evaporation of water at the outlet of the water applicators during nonirrigation periods.

Calcium and iron precipitates are a common problem with many well waters. An analysis of the water can indicate if the bicarbonate (the typical source of calcium) or iron concentration is high enough to cause precipitation. A bicarbonate concentration greater than 2 meq/L (120 ppm) coupled with a pH greater than 7.5 is likely to produce calcium deposits. Injecting inexpensive acid to lower the pH to between 5.5 and 7.0 effectively prevents calcium precipitation. Acid treatments at the end of each irrigation or on a periodic basis is frequently practiced to reduce costs. Typically, acid is injected at roughly 0.02 to 0.2% of the system capacity. If more acid than 0.2% is required to lower pH where bicarbonate concentrations are high, it is generally more practical and less expensive to aerate the water and hold it in a reservoir until it reaches chemical equilibrium and the precipitate settles out rather than adding acid.

As little as 0.3 ppm of iron present in the soluble ferrous form in the irrigation water can cause precipitation in a microirrigation system. In the presence of oxygen, the iron oxidizes to the insoluble ferric form which causes a reddish-brown precipitate. If iron is a potential hazard, it should be precipitated deliberately and filtered out before the water enters the microirrigation system. A chemical feeder can be set to provide a measured volume of a chlorine solution to oxidize iron and other organic compounds present. A residual chlorine concentration of 1.0 ppm is normally provided to avoid precipitation. Sodium hyperchlorite is preferred over calcium hyperchlorite as a source of chlorine because of the potential for calcium precipitation. Where iron concentrations are as high as 10 ppm, aeration by a mechanical aerator and sufficient settling time in a reservoir is another practical method of controlling iron.

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