Numeric Modelling of Exhaust Gas Flow in Cement Production

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Dmitrii Ivnev
  • Roland Scharf
  • Th. Kolbe

Research Organisations

External Research Organisations

  • Heidelberger Cement Russia, Podolsk
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Details

Translated title of the contributionNumerische Modellierung des Abgasstroms in der Zementherstellung
Original languageEnglish
Pages (from-to)61-65
Number of pages5
JournalCement International
Volume15
Issue number3
Publication statusPublished - Mar 2017

Abstract

The sales of cement, lime, steel and aluminium continue to provide an indication of the wealth of society. Together with some other industries their production stands at the start of the value-added chain and, as energy-intensive industries, they are always trying to reduce the use of energy without compromising the properties and quality of the products. The characteristics variables here are essentially the CO 2 emissions, the carbon footprint and the energy efficiency. Numerous process engineering measures have been taken in the past to lower the energy usage. Moving the calcination of the limestone to the preheater, the use of a pre-calciner or the use of alternative, biogenic, raw materials and fuels can be mentioned here as examples. Efficiencies were achieved that are exemplary for thermal processes. Refractory products, which are located further along the value-added chain, are indispensable for the production of cement and lime [1]. The installation of thermally insulating refractory bricks in rotary kilns and the backing of brickwork with insulating materials have therefore also been known for a long time [2 to 4]. However, new developments offer further potential for lowering the use of energy and increasing the energy efficiency still further. Processes are coming increasingly to the fore that were formerly not considered because their energy-saving potential seemed low but will have to be taken into account in the future. This includes, for example, the heating procedure after a kiln stoppage. The examples of new developments in refractory technology that are described in this article are representative of the intensive interchange between customers and refractory developers and underline the potential for innovation.

ASJC Scopus subject areas

Sustainable Development Goals

Cite this

Numeric Modelling of Exhaust Gas Flow in Cement Production. / Ivnev, Dmitrii; Scharf, Roland; Kolbe, Th.
In: Cement International, Vol. 15, No. 3, 03.2017, p. 61-65.

Research output: Contribution to journalArticleResearchpeer review

Ivnev, D, Scharf, R & Kolbe, T 2017, 'Numeric Modelling of Exhaust Gas Flow in Cement Production', Cement International, vol. 15, no. 3, pp. 61-65.
Ivnev, D., Scharf, R., & Kolbe, T. (2017). Numeric Modelling of Exhaust Gas Flow in Cement Production. Cement International, 15(3), 61-65.
Ivnev D, Scharf R, Kolbe T. Numeric Modelling of Exhaust Gas Flow in Cement Production. Cement International. 2017 Mar;15(3):61-65.
Ivnev, Dmitrii ; Scharf, Roland ; Kolbe, Th. / Numeric Modelling of Exhaust Gas Flow in Cement Production. In: Cement International. 2017 ; Vol. 15, No. 3. pp. 61-65.
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