Categories: All - environmental - optimization - particles

by Rein Vainik 8 years ago

335

Sample Mind Map

The text discusses various aspects of grain refinement in aluminum production. It highlights the challenges associated with varying efficiencies of grain refiners, which are potentially due to differences in particle size distribution.

Sample Mind Map

Grain refinement

Problem statements

Large variations in grain refiner efficiencies Probably due to particle size distribution
Particle measurements
Grain refinement tests

Consensus on theory

Favourable growth conditions
Low levels of poisonous elements
High alloying
Titanium
Narrow particle size distribution

Optimization benefits

Underämne
Quality improvement - less amount of boride particles
Lower cost

Current usage

Average addition rate where Optifine is used is < 0.3 kg/t, i.e. 75 % less. If extended to whole consumption of grain refiners, 25 000 tonnes will propably suffice to grain refine all aluminium.
Annual consumption of 80 million tonnes of Al is grain refined with 100 000 tonnes of grain refiner = 1.25 kg/t

Growth

Type of alloying element
Strength of growth restriction factor

Phase diagram data. Element k m (k-1)m Ti 9 30.7 245 Si 0.14 -7.1 6.1 Mg 0.51 -6.2 3.0 Fe 0.02 -3 2.9 Cu 0.17 -3.4 2.8 Zn 0.4 -1.6 1.0 Mn 0.94 -1.6 0.1

Poisoning elements: Zr, Cr, (Mn)

Nucleation

Correlation particle size - undercooling
Particle size distribution
Type of nucleus
TiB2
TiC

Grain size optimization

Larger grain size in slabs - lower rolling forces? Will larger grain sizes in billets have benficial effects for extrusion?
What are the optimum grain sizes in various alloys in relation to casting processes, e.g. billet, slab, sheet etc. Much can be saved by enough grain refiner to obtain safe casts.

Enironmental aspects

Long transports from producer to user
KBF4 K2TiF6 Release of F2 to atmosphere Formation of HF