Abstract
There has been a great deal of focus on the optimization of tuyere arrangements in SKS bottom blown copper smelting furnaces since the last decade, as the improved furnace operation efficiency of SKS technology has potential that cannot be ignored. New –x + 0 + x deg tuyere arrangements with 14 tuyeres are proposed in this research paper. Using a previously verified numerical model, CFD tests on the velocity distribution and wall shear stress for scaled-down SKS furnace models were conducted, with a constant total volumetric gas flow rate, and different operating parameters and furnace cross-section geometries. The results indicate that, at a relatively low gas injection speed compared with the previously optimized tuyere arrangement, although the –x +0 +x deg tuyere arrangements are unable to supply enhanced agitation in the typical round furnaces, they achieve better performance in elliptical furnaces. At a comparatively higher gas injection speed, the – x + 0 + x deg tuyere arrangements can improve the agitation performance in a round furnace while maintaining an acceptable wall shear stress on the bottom and side wall. The agitation enhancement with the − x +0 +x deg tuyere arrangements can essentially be attributed to stronger interactions between bubble plumes and furnace side walls. To further exploit the advantages of the new tuyere arrangements, an optimized tuyere angle was confirmed by a full-scale furnace model simulation.
Highlights
COPPER production technologies have been continuously optimized and updated, due to the large demand from the global copper market.[1]
The new tuyere arrangements are evaluated by comparison with the previous optimized case in the performance of velocity distribution and wall shear stress
The dead zone for scaled-down SKS furnace baths is defined as the region with a matte velocity of less than 0.05 m sÀ1
Summary
COPPER production technologies have been continuously optimized and updated, due to the large demand from the global copper market.[1] The world consumption of refined copper has witnessed a growing trend for over a hundred years since the beginning of the last century.[2] Such a growing market and changing raw materials (lower grade ores) have given rise to new developments in furnaces and supporting facilities. Alongside the use of flash smelting technology, which accounts for over half of the total copper production capacity,[2] new bath smelting technologies have been developed and promoted. The bottom blown copper smelting process, referred to as SKS (Shui Kou Shan) technology, has attracted growing interest since the last decade, due to its good, productive, and environmental performance.[3] as a bath smelting furnace, the SKS furnace is more suitable for secondary (scrap) raw materials than flash smelting
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