S. Veesler et al., ATTRITION OF HYDRARGILLITE (AL(OH)3) - MECHANISM AND QUANTIFICATION OF PARTICLE FRAGILITY BY A NEW ATTRITION INDEX, Powder technology, 75(1), 1993, pp. 49-57
International standards and specifications require that the alumina pa
rticles obtained by calcination of hydrargillite aggregates are large
enough to avoid breakage and dustiness during mechanical carrying and
handling. The particle fragility is generally estimated by an attritio
n index obtained by comparing the initial and final sizes of particles
undergoing an attrition test. In the present work we modify this test
and apply it to samples of hydrargillite aggregates from different or
igins, with different internal structures and particle size distributi
ons. It is shown that the commonly used attrition index is affected by
size distribution and attrition mechanism. In addition, it does not r
eally describe the particle fragility. Therefore, we propose a real fr
agility index named F30 which is not only independent of the particle
size but also gives some information on the attrition mechanism. If F3
0 < 20, hydrargillite is strong and attrition occurs by abrasion. If F
30 > 20, hydrargillite is weak and attrition occurs more by breakage o
f the aggregates than by abrasion.