Study of the kinetics of carbon reduction of matte/oxysulfide/slag in nickel/copper flash smelting.
Our rough guess is there are 55,250 words in this book.
At a pace averaging 250 words per minute, this book will take 3 hours and 41 minutes to read. With a half hour per day, this will take 8 days to read.
How long will it take you?
This book will take an estimated to read at a reading speed averaging words per minute. With 30 minutes per day, this will take to read.
Enter your reading speedYou can take one of our WPM reading speed tests to find your reading speed.
Create a free account to track your reading progress, build your reading list, and set reading goals.
Word Count
55,250 words, Guess
Page Count
221 pages
Identifiers
- ISBN-10061294445X
- ISBN-139780612944459
- Open LibraryOL19887297M
Description
A new operating concept for the Inco flash furnace was investigated. A supernatant coke layer would be added onto the surface of the molten bath to establish a reducing barrier between the slag and the freeboard. The partially oxidized sulfide mineral particles would thus be reduced while percolating through the coke layer to yield sulfur deficient (partially metallized) matte. The iron activity of sulfur deficient mattes is higher than that of regular mattes, and this coke barrier should lead to higher nickel and cobalt recoveries. The main challenge for the success of the new operating concept is to create conditions that optimize the rate of reduction without affecting furnace throughput and without requiring changes in furnace geometry. To achieve this objective it is necessary to develop an in depth understanding of the mechanism and basic chemistry of coke reduction of the flash flame products.Experiments were conducted in a miniplant flash furnace to investigate the feasibility and merits of this process scheme. The miniplant flash furnace test work also ties the results of graphite reduction tests with flash smelting operation. The test work suggests that coke reduction of partially oxidized sulfide mineral particles takes advantage of the fast reduction rate of matte, thus resulting in magnetite-coke reduction, with the production of metallic iron prior to the formation of slag. As a result, the reduction rate is optimized, sulfur deficient (metallized) matte is produced, and a significant improvement in matte/slag cobalt partition is achieved. All these objectives were met in the miniplant tests while flash smelting at a throughput per unit area of molten bath similar to that of the commercial Inco flash furnace.A complete investigation of the reduction mechanism was conducted utilizing all of the test results, thermodynamic calculation, samples of burner flame particles, samples of the matte and slag, SEM and XRD analysis, multiphase CFD modeling and TGA test work.Coke reduction of the flash flame products, i.e. partially oxidized sulfide mineral particles, was simulated by graphite-oxysulfide and graphite-matte reduction test work in this study. Graphite-slag reduction was also conducted for comparison. The graphite reduction tests were divided into two separate parts, X-ray visualization tests and crucible graphite reduction tests. The X-ray visualization tests confirmed that (1) oxysulfide and matte have much better wettability of graphite than slag; (2) the slag reduction product gas is discharged through a gas film on the surface of graphite; (3) the rate of reduction of oxysulfide and matte is visually faster than that of slag. The crucible graphite reduction tests measured the rate of graphite reduction of oxysulfide, matte, slag and a mixture of matte + slag at various temperatures utilizing an on-line gas analyzer. The results clearly show that the rates of reduction of matte and oxysulfide are several times faster than that of slag.
Subjects
Links
Reader Reviews
No reviews yet for this book.
Be the first to share your thoughts!