Journal of Biosystems Engineering

Korean Society for Agricultural Machinery (한국농업기계학회)
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Milling Characteristics of Milled Rice According to Milling Ratio of Friction and Abrasive Milling

마찰과 연삭 도정배분에 의한 쌀의 도정특성

  • Published : 2009.12.25
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Abstract

This study was performed to investigate the optimum abrasive and friction milling ratio. This was accomplished by determining changes in the quality, such as whiteness, moisture content, broken kernel, unstripped embryo rate, and surface characteristics or milling difference, during an abrasive and friction based milling process. When only abrasive was milled, the increase of whiteness was fast in the first milling, whereas the increasing rate of whiteness was small in the latter milling. The decreasing rate of moisture content and broken kernel increased as the friction milling ratio was increased. Combining with the friction milling was considered a suitable method because the unstripped embryo rate was high only when abrasive milling was used. In the case of a high abrasive milling ratio, a significant milling difference was observed in the initial milling. This indicated that the milling difference was not completely eliminated despite using friction milling in the latter milling. Consequently, it was necessary to minimize the milling difference in the initial milling. When milling quality was synthetically considered, the abrasive milling ratio was varied from 20~50%. When the abrasive milling ratio was greater than 40%, the external quality of the rice milled deteriorated since holes and defects generated on the surface in the initial milling were not removed. Due to this deterioration in surface characteristics, an abrasive milling ratio of 30% was identified as a suitable level.

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References

  1. Agricultural Cooperatives (NongHyup). 1992. Handbook of Rice Processing Complex. pp.156. Agricultural Cooperatives
  2. Archer, T. R and T. J. Siebenmorgen. 1995. Milling quality as affected by brown rice temperature. Cereal Chemistry 72:304-307
  3. Barber, S. and C. B. de Barber. 1979. Outlook for rice milling quality evaluation system. Proceeding of the workshop on chemical aspects of rice grain quality. pp. 209. International Rice Research Institute
  4. Hosokawa, A., T. Ban., I. Yokosawa., H. Yanase and S. Chikubu. 1995. Rice Post-harvest Technology. p. 22, 421-425. The Food Agency, Ministry of Agriculture, Forestry and Fisheries, Japan
  5. Kawamura, S. 1990. Rice milling, and quality and taste of milled rice (part 2), Milling characteristics. Faculty of Agriculture, Hokkaido University 17:25-49
  6. Kawamura, S., K. Itoh and Y. Ikeuchi. 1981. The milling characteristics of \he combined rice pearling system of grinding type machine and friction type machine. Hokkaido Branch Report of Japanese Society of Agricultural Machinery 21:74-79
  7. Kim, H., O. W. Kim., H. J. Lee., D. C. Kim and S. J. Hong. 2006. Analysis of actual state of milling in RPC. Proceeding of the Korean Society for Agricultural Machinery Conference 11(1):218-223
  8. Kim, O. W., H. Kim., D. C. Kim and S. S. Kim. 2005a. Determination of whiteness condition for efficient milling in rice processing complex. Journal of Biosystems Engineering 30(4):242-248 https://doi.org/10.5307/JBE.2005.30.4.242
  9. Kim, O. W., H. Kim and S. E. Lee. 2005b. Color modeling of milled rice by milling degree. Korea Journal Food Preservation 12(2):141-145
  10. Koide, S., Y. Nishiyama and Y. Takikawa. 1998. Studies on abrasive rice milling (part 1). Journal of the Japanese Society of Agricultural Machinery 60:19-26
  11. Korea Society for Agricultural Machinery. 1998. Handbook of agricultural machinery. Korea Society for Agricultural Machinery. pp. 234
  12. Mesaki, T., T. Satake., T. Fukumori and Y. Ikeda. 2005. Journal of the Japanese Society of Agricultural Machinery 67:61-71
  13. Mukai, T. 1998. New technology in rice mill plant. Journal of the Japanese Society of Agricultural Machinery 60:160-163
  14. Satake, T., T. Fukumori., H. Liu., M. Kawano and Y. Sasaki. 2004. Development of processing technology for highly functional rice (part 2). Journal of the Japanese Society of Agricultural Machinery 66:91-97
  15. Yanase, H and K. Ohstubo. 1985. Relation between rice milling methods and palatability of cooked rice (part 1). Report National Food Research Institute 46:148-161
  16. Yoon, D. H., O. W. Kim and H. Kim. 2006. Modeling of milling degree for milled rice using NMG dying and image processing. Journal of Biosystems Engineering 31(6):524-528 https://doi.org/10.5307/JBE.2006.31.6.524

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