Mekanik öğütme yöntemi ile üretilen mikronaltı Al2O3 seramik parçacıklarının fiziksel özellikleri üzerine öğütme zamanı, öğütme hızı ve bilye toz ağırlık oranının etkisi

Yıl 2018, Cilt: 24 Sayı: 4, 635 - 642, 17.08.2018

Temel Varol

Öz

Bu
çalışmada mekanik öğütme yöntemi ile kaba toz boyutuna sahip Al₂O₃
(Alüminyum Oksit) tozlarından mikronaltı ve nano toz boyutuna sahip Al₂O₃
tozlarının üretimi amaçlanmıştır. Aynı zamanda mekanik öğütme işlemine tabi
tutulan Al₂O₃ tozlarının morfolojisi, parçacık boyutu,
özgül yüzey alanı, görünür yoğunluğu ve mikroyapısı üzerine mekanik öğütme
parametreleri olan öğütme zamanı, öğütme hızı ve bilye toz ağırlık oranının
etkisi araştırılmıştır. Morfoloji incelemeleri için taramalı elektron
mikroskobu kullanılmıştır. Al₂O₃ tozlarının ortalama
parçacık boyutu ve özgül yüzey alanı parçacık boyutu ölçüm cihazı ile
araştırılmıştır. Görünür yoğunluk değerleri hall akış metre cihazı kullanılarak
ölçülmüştür. Morfoloji incelemeleri, başlangıçta köşeli morfolojiye sahip Al₂O₃
parçacıklarının artan öğütme hızı ile düzensiz ve küresele yakın bir
morfolojiye dönüştüğünü göstermiştir. Parçacık boyutu değerleri incelendiğinde
boyut azalışındaki en etkin mekanik öğütme parametresinin öğütme hızı olduğu
belirlenmiştir. Elde edilen en düşük parçacık boyutu değeri 320 nm olup bu
değere 300 devir/dk. 5 sa. ve 15:1 toz bilye ağırlık oranı şartlarında ulaşılmıştır.
Al₂O₃ tozlarının 48 mikron değerindeki başlangıç boyutu
ile 5 sa. kısa bir öğütme süresi sonunda elde edilen 320 nm’lik parçacık boyutu
karşılaştırıldığında mekanik öğütme işleminin seramik toz öğütme işlemi üzerine
etkisi açık bir şekilde ortaya konmuştur.

Anahtar Kelimeler

Mekanik öğütme, Al2O3 seramik tozları, Öğütme hızı, Toz boyutu

The effect of milling time, milling speed and ball to powder weight ratio on the physical properties of submicron Al2O3 ceramic particles fabricated by mechanical milling method

Öz

The
aim of this study is the fabrication of submicron and nano Al₂O₃
ceramic powders from coarse Al₂O₃ (Alumina) ceramic
powders by mechanical milling method. The effect of mechanical milling
parameters such as milling time, milling speed and ball to powder weight ratio
on the morphology, particle size, specific wear rate, apparent density and
microstructure of milled coarse Al₂O₃ powders is also
investigated. Scanning electron microscope is used for morphology examination.
The average particle size and specific surface area are investigated by a
particle sizer. The apparent density values are measured by using a hall
flowmeter. Morphology examinations showed that the polygonal morphology of Al₂O₃
powders is changed to irregular and spherical morphology with increasing
milling speed. When the particle size values investigated, it is found that the
most effective parameter for particle size refinement is the milling speed. The
lowest particle size of Al₂O₃ powders is 320 nm which is
obtained with 300 rpm of milling speed, 5h of milling time and 15:1 of ball to
powder weight ratio. When the initial size of the Al₂O₃
powders with 48 micron and 320 nm of final particle size at obtained at the 5h
of milling are compared, the effect of mechanical milling on the milling
process of ceramic powders is clearly demonstrated.

Anahtar Kelimeler

Mechanical milling, Al2O3 ceramic powders, Milling speed, Particle size

Kaynakça

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