Abstract
Permeability of polymer coatings on urea varies greatly with the type of polymer. A conventional test of measuring the effectiveness of coating involves a 7d static dissolution rate of coated urea into concentrated urea solution, but the results are only qualitative. Our approach was, instead, to make quantitative measurements of permeability, and so make more accurate predictions of release rate of urea across a membrane. A simple device, consisting of a container attached to vertical pipes at the bottom, was constructed to determine permeability of coats on urea granules. A turbulent flow of water ran over a 2 cm pack of coated-urea granules so urea did not accumulate at the outer surface of the coated granules. Separate determinations with two thicknesses of coats (8.8 and 14.7µm) were conducted with water at 12 or 31°C. Permeability and activation energy of permeability were calculated. A comparison was also made between release rate of urea calculated from permeability and that determined by 7d dissolution rate method at 23°C. Nearly 100 h were required for 100% release with the thick coating, but only 20% urea was released after 168 h with the 7d dissolution rate method.
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References
Attoe OJ, Rasson FL, Dahnke WC and Boyle JR (1970) Fertilizer release from packets and its effect on tree growth. Soil Sci Soc Am Proc 34: 137–142
Baker RW (1987) Controlled Release of Biologically Active Agents, pp 2–50. John Wiley and Sons, Inc., New York
Blouin M, Rindt W and Moore O (1971) Sulfur-coated fertilizers from controlled release: Pilot plant production. J Agric Food Chem 19: 801–808
Burnette RR (1987) Theory of Mass Transfer. In: Robinson J and Lee VHL (eds) Controlled Drug Delivery: Fundamentals and Applications, pp 95–138. Marcel Dekker, Inc., New York
Christianson CB (1988) Factors affecting N release of urea from reactive layer coated urea. Fert Res 16: 273–284
Fan LT and Singh SK (1989) Controlled Release, A quantitative treatment, pp 49–61. Springer-Verlag, New York
Hassan ZA, Young SD, Hepburn C and Arizal R (1990) An evaluation of urea rubber matrices as slow-release fertilizers. Fert Res 22: 63–70
Kincl FA and Rudel HW (1971) Sustained release hormonal preparations. Acta Endocrinol Suppl 151: 5–30
Lu SM and Lee SF (1992) Slow release of urea through latex film. J Controlled Release 18: 171–180
Lunt DR and Oertli JJ (1962) Controlled release of fertilizer minerals by encapsulating membranes. II. Efficiency of recovery, influence of soil moisture, mode of application, and other considerations related to use. Soil Sci Soc Am Proc 26: 584–587
Pratt C and Noyes R (1965) Nitrogen Fertilizer Chemical Processes, pp 203–204. Nyes Development Corp, New York
Rogers CE (1976) Structure factors governing controlled release. In: Paul DR and Harris FW (eds) Controlled Release Polymeric Formulation, pp 15–25. ACS Symposium Series, Washington
Salman OA (1988) Polymer coating on urea prills to reduce dissolution rate. J Agric Food Chem 36: 616–621
Savant NK, Clemmons JR and James AF (1982) A technique for predicting urea release from coated urea in wetland soil. Comm Soil Sci Plant Anal 13: 793–802
Tojo K, Miyanami K and Fan LT (1983) Mathematical simulation membrane-moderated controlled release. Powder Technol 35: 89–96
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Zhang, M., Nyborg, M. & Ryan, J.T. Determining permeability of coatings of polymer-coated urea. Fertilizer Research 38, 47–51 (1994). https://doi.org/10.1007/BF00750061
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DOI: https://doi.org/10.1007/BF00750061