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MINING AND PROCESSING CONTROL AND AUTOMATION
ArticleName Features of the proprietary system of automatic analytical control ASAK-RIVS for mining and processing plants
DOI 10.17580/gzh.2016.11.13
ArticleAuthor Bondarenko A. V., Nikandrov I. S., Andreev D. S.
ArticleAuthorData

IVS Joint Venture, Saint-Petersburg, Russia:

A. V. Bondarenko, Head of Analytical Center, Candidate of Engineering Sciences, A_Bondarenko@rivs.ru
I. S. Nikandrov, Head of System Engineering Sector of Analytical Center
D. S. Andreev, Head of Technical and Mathematical Research Sector of Analytical Center

Abstract

The authors present the objective conditions for creation of the proprietary automatic analytical control system ASAK-RIVS for mining and processing industry, including pulp assaying and analytical units. The composition and structure of the equipment is described. It is emphasized that design of the automatic X-ray fluorescence pulp analyzer as the backbone of the analytical unit is challenging. At the same time, this type analyzer is the highest-needed sensor of element composition for monitoring and control of process stages in ore beneficiation. The authors specify features of the proprietary multi-cell pulp analyzer and compare its detection limits with the performance of different X-ray fluorescence powder and pulp analyzers. It is highlighted in the article that the analytical unit based on the X-ray fluorescence pulp analyzer (RFA-RIVS) has been designed based on the unified programming, technical, mathematical and metrological decisions. Also, a validated approach to assessment of necessary and sufficient sensitivity of assaying and operating analytical control is presented. The advantages of ASAK-RIVS over the similar analytical systems are identified. Finally, it is concluded on conformity of the designed and patented RFA-RIVS and ASAK-RIVS systems with the modern requirements imposed on the same systems of instrumental express-analysis.

keywords Automatic analytical control system, X-ray fluorescence analyzer, analytical unit, test parameters, assaying sensitivity, concentrates
References

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