Fertilizer Mixer Performance Evaluation using Chloride Titration

Authors

  • Yi-Cheng Hsieh Office of the Texas State Chemist
  • Timothy Herrman State Chemist and Director, Office of the Texas State Chemist

DOI:

https://doi.org/10.21423/JRS-V06N02P008

Keywords:

Fertilizer blending, Performance evaluation, Mixer performance

Abstract

Mixing processes are a critical step in manufacturing blended fertilizer products. Although each stage of the production process is monitored to prevent deficiencies and ensure quality in fertilizer production, evaluation of mixing performance by regulatory agencies are the keys to assessing quality of the final product. The Office of the Texas State Chemist (OTSC) conducted a fertilizer mixer evaluation study, which involved two main components: sample collection and lab analyses. Samples from 9 mixers were collected from 7 fertilizer manufacturing locations in Texas. Firms were selected based on the type of fertilizer components currently in use and the type of mixer(s), which included cement type, vertical, volumetric and paddle. Sample collection follows the process outlined by The Fertilizer Institute (TFI). Samples are collected from the blended product and from the individual raw ingredient materials. In the laboratory, the samples from the individual raw materials and blended product stream cut samples were analyzed for size guide number (SGN), density, particle number, and nitrogen (N)-phosphorous (P)-potassium (K) levels, and Chloride (Cl-) content. The sample accuracy was calculated by comparing the actual formula weights to the expected values for the blended product. To determine mixer efficiency and reproducibility, coefficient of variations were calculated to determine the variability between various samples of the blended product. Our results indicated Cl- titration is a cost effective method to efficiently evaluate mixer performance, the mixing time of tested cement mixer may result in high variation in the N-P-K analysis, and Cl- level in blended samples. Based on our previous feed mixer study, facilities operating these cement mixers may consider to check mixer readiness and increase mixing time to achieve better homogeneity.

https://doi.org/10.21423/jrs-v06n02p008 (DOI assigned 1/24/2019)

References

Anaka, A., Wickstrom, M., & Siciliano, S. D. (2008). Biogeochemical toxicity and phytotoxicity of nitrogenous compouds in a variety of arctic soils. Environmental Toxicology and Chemistry, 27(8), 1809-1816.

AOAC International. (1995). Official Methods of Analysis, 16th Ed. Association of Official Analytical Chemists, Washington, DC.

Brammell, W. S. (1974). Collaborative study of a potentiometric titration method for determining sodium chloride in foods. Journal of Association of Official Analytical Chemists, 57, 1209-1216.

Cundall, P. A. & Strack, O. D. L. (1980). A discrete numeriacl model for granular asseblies - Reply. Geotechnique, 30, 335-336.

Engelsberger, W. R. & Schulze, W. X. (2012). Nitrate and ammonium lead to distinct global dynamic phosphorylation patterns when resupplied to nitrogen-starved Arabidopsis seedlings. Plant Journal, 69, 978-995.

Fixen, P. E. & West, F. B. (2002). Nitrogen Fertilizers: Meeting Contemporary Challenges. Ambio, 31, 169-176.

Garbotz, G. (1929). Performance tests on concrete mixers. Zeitschrift Des Vereines Deutscher Igenieure, 73, 773-781.

Gupta, A. P. (2005). Micronutrient status and fertilizer use scenario in India. Journal of Trace Elements in Medicine and Biology, 18, 325-331.

Hall, B. (1996). Bulk Blend Quality Control Manual. The Fertilizer Institute, Washington, DC.

Harner III, J. P., Behnkw, K., & Herrman, T. (1995). Rotating Drum Mixers, MF2053. Kansas State University.

He, Z. L., Yang, X. E., & Stofella, P. J. (2005). Trace elements in agroecosystems and impacts on the environment. Journal of Trace Elements in Medicine and Biology, 19(2-3), 125-140.

Herrman, T., & Behnke, K. (1994). Testing Mixer Performance, MF3393. Kansas State University Agricultural Experiment Station and Cooperative Extension Service Bulletin, Manhattan, KS: Kansas State University.

Herrman, T., & Behnke, K. (2002). Horizontal and Vertical Mixers, GRSI-1004. Kansas State University Agricultural Experiment Station and Cooperative Extension Service.

International Fertilizer Development Center. (1998). Fertilizer Manual. Dordrecht, The Netherlands: Kluwer Academic.

Kepintski, J., & Blaszkiewicz, G. (1966). Direct potentiometric titration of chlorite in presence of chlorate, chlorine dioxide and chloride. Talanta, 13, 357-362.

Lawlor, D. W. (2002). Carbon and nitrogen assimilation in relation to yield: mechanisms are the key to understanding production systems. Journal of Experimental Botany, 53, 773-787.

Li, H., Li, T., Fu, G., & Katulanda, P. (2013). Induced leaf intercellular CO2, photosynthesis, potassium and nitrate retention and strawberry early fruit formation under macronutrient limitation. Photosynthesis Research, 115, 101-114.

Manickam, S. S., Shah, R., Tomei, J., Bergman, T. L. & Chaudhuri, B. (2010). Investigating mixing in a multi-dimensional rotary mixer: Experiments and simulations. Powder Technology, 201, 83-92.

Mortvedt, J. J. & Giordano, P. M. (1970). Application of Micronutrients Alone or with Macronutrient Fertilizers. Fert. Abstr Pap Am Chem S: 3-7.

Newlon, N., Coxtrout, C. & Kane, P. (1993). Evaluation of Current AOAC Fertilizer Sample Preparation Requirements. Journal of AOAC International, 76, 1174-1181.

Northrop, J. H. (1948). A convenient method for potentiometric titration of chloride ions. Journal of General Physiology, 31, 213-215.

Rygh, O. (1952). Research on the trace elements. VI. The influence of fertilizer with added trace elements on the quantity of vitamin R and of 1. ascorbic acid in plants. Bulletin De La Societe De Chimie Biologique (Paris) 34, 828-830.

Wilcox, R. A. & Balding, J. L. (1976). Feed manufacturing problems: incomplete mixing and segregation. Feedstuffs, 33-34.

Downloads

Published

2018-11-05

Issue

Vol 6, No 2 (2018)

Section

Scientific Articles

License

Copyright (c) 2018 Journal of Regulatory Science

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

By submitting content to the Journal of Regulatory Science (JRS), authors agree to the following terms:

  1. Authors retain copyright and grant the JRS the right of first publication. Authors retain patent, trademark, and other intellectual property rights (including research data) and grant third parties the right to use, reproduce, and share the article according to the Creative Commons — Attribution-NonCommercial 4.0 International — CC BY-NC 4.0 license agreement. The JRS is an open access journal and, as a result, articles are free to use with proper acknowledgment of the work's authorship and initial publication in this journal.

  2. Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process.

  3. If excerpts from other copyrighted works are included, the author(s) must obtain written permission from the copyright owners and credit the source(s) in the article.

  4. The publication of the submission has been approved by all co-authors and responsible authorities at the institute or organization where the work has been carried out.

  5. Copyright has not been breached in seeking publication of the submission.