Ultrasonic velocity measurements in powders and their relationship to strength in particles formed by agglomeration

Many industries produce pellets, powders, and granules as finished or intermediate products. The strength of these products is important to their marketability, as dusting and breakdown from weak product is undesirable and results in poor handling properties. Measurement of “strength” usually takes...

Full description

Saved in:
Bibliographic Details
Published in:Powder technology 2011-04, Vol.208 (3), p.694-701
Main Authors: Coghill, P.J., Giang, P.
Format: Article
Language:English
Subjects:
Alumina
Aluminum oxide
Applied sciences
Attrition
bulk density
Chemical engineering
composite materials
correlation
crushing
dusting
Exact sciences and technology
Glass
granules
Grinding
industry
Iron
Miscellaneous
Particle strength
Particulate composites
Pellets
Powder
powders
Sintering, pelletization, granulation
Solid-solid systems
Sound velocity
Strength
Ultrasonic velocity
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Many industries produce pellets, powders, and granules as finished or intermediate products. The strength of these products is important to their marketability, as dusting and breakdown from weak product is undesirable and results in poor handling properties. Measurement of “strength” usually takes the form of some empirical test involving crushing or attrition. The possibility of using sound velocity measurements to replace these techniques (especially for composite materials such as pellets or agglomerates) is investigated by performing measurements on glass sphere powders and test industrial materials. The ultrasonic velocity measurements in glass spheres were shown to be described by effective medium theories of sound propagation and can be used to probe the packing structure of the powder. For coarser powders sensible values of the co-ordination number Z could be calculated during compaction of the material. For powders finer than 0.2 mm the sound velocity measurements are no longer repeatable and rapid changes of the configuration may occur though the packing density only changes slowly. Two industrially important materials, iron ore pellets and calcined alumina powders were studied. It was found that reproducible measurements can be made in these materials that correlate to standard industrial “strength” measurements. In the case of iron ore pellets the correlation coefficient was 0.94 and the variability of the sound velocity based “strength” measurement was a factor of five smaller than the particle breakage method. For alumina powders the standard attrition index measurements could be correlated with the ultrasonic velocity and bulk density for both hydrated and calcined alumina powders with correlation coefficients of up to 0.95. The sound velocity strength measurement technique has significant advantages in repeatability, sample size and provides direct measurement of a physical parameter related to strength. Sound velocity measurements were related to particle strength in iron ore pellets and alumina powders. In glass powders effective medium theories were found to describe sound behaviour with characteristic 1/6 power law behaviour. It was found for alumina powder the sound velocity and attrition index (Al) correlated. [Display omitted] ► Sound velocity in an agglomerated particles is related to particle strength. ► In powders of such particles sound speed can be related to particle strength. ► In glass beads sound speed can be used to monito
ISSN:0032-5910
1873-328X
DOI:10.1016/j.powtec.2010.11.040