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Power Engineering
ArticleName Primary diagnosis of energy efficiency in an integrated steel plant, based on intensive energy-saving methodology. Part 2
DOI 10.17580/cisisr.2022.01.20
ArticleAuthor S. V. Kartavtsev, E. G. Neshporenko, S. V. Matveev
ArticleAuthorData

Nosov Magnitogorsk State Technical University (Magnitogorsk, Russia):

S. V. Kartavtsev, Dr. Eng., Prof., Dept. of Heat Engineering and Power Engineering Systems, e-mail: kartavzw@mail.ru
E. G. Neshporenko, Cand. Eng., Associate Prof., Head of the Dept. of Heat Engineering and Power Engineering Systems
S. V. Matveev, Engineer, Dept. of Heat Engineering and Power Engineering Systems

Abstract

The energy efficiency of the integrated steel plant is studied basing on the intensive energy conservation methodology. The primary diagnostics of the energy efficiency of the integrated steel plant is carried out. The boundaries of the research object are established from iron ore deposits to finished cold-rolled steel sheet. The thermophysical heat absorption of materials and intermediates within the boundaries of a closed heat engineering complex has been estimated. The energy intensity of the cold-rolled steel sheet within the same boundaries has been calculated. Efficiency of production was estimated by comparing heat consumption and energy intensity. The complete intensive energy conservation reserve in the complex has been determined. Reserve structure is studied and directions of its implementation are discussed. It is shown that the most complete implementation of the energy-saving reserve is possible only with the transition of a new generation of steel engineering and technology.

keywords Energy efficiency, integrated steel plant, intensive energy saving methodology, graph theory, network flows, heat consumption and energy intensity, primary diagnosis of energy efficiency, energy saving reserve and its structure, directions of technical progress of metallurgical engineering and technology
References

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