Guidelines to adjust particle size distributions by wet comminution of a bioactive glass determined by Taguchi and multivariate analysis

authors	Ben-Arfa, BAE; Salvado, IMM; Frade, JR; Pullar, RC
nationality	International
journal	CERAMICS INTERNATIONAL
author keywords	Ball milling; Weibull fitting; Bimodal; Multimodal; Particle size distribution (PSD); Sol-gel derived glass
keywords	RHEOLOGY; BEHAVIOR; PACKING
abstract	A quaternary bioactive glass of high silica content was used as a model system for flexible design of powder characteristics obtained by ball milling. The dependence on milling time was used to demonstrate consistency with the expected correlation between comminution and cumulative kinetic energy of impacting balls. Additional experiments were based on Taguchi planning of simultaneous changes in milling time, balls-to-powder ratio and ethanol-to-powder ratio, with ethanol used as a process control agent (PCA) to prevent agglomeration and to seek greater flexibility in the design of powder distributions. Plausible physical mechanisms allowed us to obtain improved fitting by multivariate analysis, based on log-log scales. Normal distribution was found to be well-suited to describe the actual particle size distributions, which are very positively skewed. Weibull distributions provided good fitting, mainly by considering the three different contributions from particles in small, medium and large size ranges. These contributions are affected differently by ball milling parameters, as demonstrated by finer analysis. This yields suitable conditions for a flexible design of asymmetric powder size distributions (i.e. bimodal or skewed), in addition to a decrease in average particle size - both highly significant factors when designing glass-ceramic powders for robocasting and additive manufacturing.
publisher	ELSEVIER SCI LTD
issn	0272-8842
year published	2019
volume	45
issue	3
beginning page	3857
ending page	3863
digital object identifier (doi)	10.1016/j.ceramint.2018.11.057
web of science category	Materials Science, Ceramics
subject category	Materials Science
unique article identifier	WOS:000456225900118