ABSTRACT
The effect of impurities on the precipitation behaviour of nickel powder produced by
high-pressure hydrogen reduction was investigated in order to determine the factors responsible
for the formation of powder with undesirable morphology. In nickel precipitation by hydrogen
reduction, two product morphologies have been observed: the spherical, open powder (desirable)
and the spherical, closing/closed powder (undesirable). Two major impurities were studied
namely; a morphology modifier (a polyacrylic acid derivative) used as an additive and iron
which is an inherent impurity. Reduction experiments to investigate the effects of the
morphology modifier were conducted on a pilot-plant scale using a 75 L autoclave with modifier
dosages in the range of 0.25-5 vol %. Experiments to investigate the effects of iron were
conducted on a laboratory scale using a 0.5 L autoclave fitted with a Teflon reaction beaker.
Both autoclaves were fitted with a double impeller configuration consisting of an upper axial
impeller and lower Rushton turbine. Iron was added to the reduction solution as ferrous sulphate
solution (acidified to pH 2.5 to prevent oxidation) to give reduction solutions with Fe2+
concentrations of 6, 20 and 200 mg/L. Reduction was conducted at a temperature between
180-190 oC and 2800 kPa pressure using a nickel ammine sulphate solution (free NH3:Ni2+ and
(NH4)2SO4:Ni2+ molar ratios of 2.0-2.1 and 2.2 respectively). Nickel powder samples were
collected from the autoclaves after each successive batch reduction (densification) within a
cycle. The powder was then separated from the mother liquor before being washed and dried for
subsequent analysis. The concentration of the nickel before and after reduction was also
measured to establish the nickel depletion rate.
The effects of the selected impurities were investigated by analysing the nickel depletion rates,
SEM micrographs, powder purity and transforming the particle size distribution (PSD) data of
the powder samples into moments. The evolution of the moments, volume or mass moment mean
size (D(4.3)), number based mean size ( L1.0 ) and BET surface area were used to generate
information on the particle rate processes responsible for powder formation. These findings were
validated by means of mathematical models based on the moment form of the population balance
equation.
The morphology modifier was found to act as a growth inhibitor, thus, decreasing the
aggregation rate and making the powder more prone to breakage. Iron was found to induce
surface nucleation, thus, creating more growth sites on the particle surface leading to an increase
in the growth rate. Based on mathematical modelling results and evidence from SEM
micrographs, the spherically shaped nickel powder particles were proposed to be formed through
the formation of a pre-cursor by secondary aggregation followed by spherulitic growth. The
degree of compactness of the spherulites (open or closed formation) was proposed to be
determined by the number of active growth sites on the nickel particle surface. The morphology
modifier was found to decrease the number of growth sites as a result of growth inhibition
leading to the production of more open spherulites which are more prone to shear-induced
breakage. Iron was found to increase the number of growth sites as a result of surface nucleation
leading to more compact spherulites which are more resistant to shear-induced breakage. Based
on these findings a modifier dosage of less than 1 vol % and Fe levels of less than 6 mg/L are
recommended if spherical, open particles are desired. Thus, by characterising the effect of any
impurity on growth it is possible to predict its impact on particle morphology.
Ntuli, F (2021). Nickel Powder Precipitation By High-Pressure Hydrogen Reduction. Afribary. Retrieved from https://track.afribary.com/works/nickel-powder-precipitation-by-high-pressure-hydrogen-reduction
Ntuli, Freeman "Nickel Powder Precipitation By High-Pressure Hydrogen Reduction" Afribary. Afribary, 15 May. 2021, https://track.afribary.com/works/nickel-powder-precipitation-by-high-pressure-hydrogen-reduction. Accessed 27 Nov. 2024.
Ntuli, Freeman . "Nickel Powder Precipitation By High-Pressure Hydrogen Reduction". Afribary, Afribary, 15 May. 2021. Web. 27 Nov. 2024. < https://track.afribary.com/works/nickel-powder-precipitation-by-high-pressure-hydrogen-reduction >.
Ntuli, Freeman . "Nickel Powder Precipitation By High-Pressure Hydrogen Reduction" Afribary (2021). Accessed November 27, 2024. https://track.afribary.com/works/nickel-powder-precipitation-by-high-pressure-hydrogen-reduction