ISSN 2594-357X
45º Ironmaking / 16º Iron Ore / 3º Agglomeration — vol. 45, num.45 (2015)
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Abstract
Each year, approximately 400 million tons of blast furnace slag is produced worldwide with a tapping temperature of around 1,500°C. It is normally used as a substitute for cement clinker or as an aggregate material in road construction. Currently, the slag is granulated in wet-granulation plants using large volumes of water and to date, it has not been possible to utilise the remnant heat energy of the molten slag, which amounts to approximately 1.8 GJ of energy per ton. However, in an R&D project currently underway led by Primetals Technolgies and industrial partners, a new dry atomising technology is being investigated to use air to cool molten slag and recover the lost heat energy. The resultant pelletised slag fulfils the same criteria as wet-granulated slag for use in the cement industry. Phase 1 of the project has now been completed where a technical plant was set up at the University of Leoben in 2012. A series of dry-slag granulation campaigns were carried out using remelted blast furnace slag. The elevated offgas temperatures and the quality of the slag product as verified by the FEhS Building Material Institute have shown the process suitability as an industrial application and the decision was taken to escalate the project from large laboratory scale to a full size pilot plant. The phase 2 development of this plant is now underway and is scheduled for installation at the site of an industrial partner in early 2016 where full slag flow will be fed directly to the plant from Blast Furnace ‘slag runners. This paper will show the development path taken to date and the planned route to our goal in 2016 of being the first to industrialise the ‘game changing’ process of dry Slag Granulation with Heat Recovery from the slag.
Keywords
Blast furnace, Dry slag granulation, Energy recovery, Cement
Cement
How to refer
McDonald, Ian James;
Werner, Andrea.
DRY SLAG GRANULATION WITH HEAT RECOVERY
,
p. 286-295.
In: 45º Ironmaking / 16º Iron Ore / 3º Agglomeration,
Rio de Janeiro,
2015.
ISSN: 2594-357X
, DOI 10.5151/4444-4444-26526