Process for the production of aluminium oxide particles

Abstract

The present invention relates to a method for the production of aluminum oxide particles of spherical morphology and with a particles size in the submicron range.

Claims

1. A process for the production of spherical submicron particles of aluminium oxide (Al.sub.2O.sub.3), wherein aluminium oxide and aluminium metal are added into a reaction vessel comprising a pool of at least aluminium oxide in molten state, serving as a heat reservoir for the process, whereby aluminium oxide reacts with aluminium metal producing aluminium sub-oxides gases and aluminium vapour, whereafter the sub-oxides and the aluminium vapour are oxidized above the molten pool of aluminium oxide to give aluminium oxide in the form of spherical submicron particles.

2. The process according to claim 1, wherein the pool of at least aluminium oxide in molten state comprises 20-50 weight % aluminium oxide and 50-80 weight % zirconium dioxide.

3. The process according to claim 1, wherein the pool of at least aluminium oxide in molten state comprises 30-55 weight % aluminium oxide and 45-70 weight % zirconium dioxide.

4. The process according to, claim 1 wherein aluminium oxide and aluminium metal are injected into the reaction vessel.

5. The process according to claim 1, wherein the oxidation of the aluminium vapour and aluminium sub-oxides is carried out in air or oxygen.

6. The process of claim 1, wherein a gas is injected into the molten pool of aluminium oxide for increasing the partial pressure of aluminium sub-oxides being released from the pool.

7. The process of claim 6, wherein the gas is an oxidizing or a neutral gas, selected from the group consisting of air or nitrogen or other inert gases.

8. The process of claim 1, wherein the obtained aluminium oxide particles are captured in a filter.

9. The process of claim 8, wherein the process further comprises removing NOx contained in the off-gases.

10. The process of claim 1, wherein calcined alumina and metallic aluminium are used as raw materials.

Description

SHORT DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a graphic illustration of the partial pressure of aluminium sub-oxide as a function of temperature, in which the partial pressure along the Y-axis is given in atmospheres.

(2) FIG. 2 is a micrograph showing an example of the particles prepared.

DETAILED DESCRIPTION OF THE INVENTION

(3) The method of the present invention is used for the production of spherical submicron particles of aluminium oxide, Al.sub.2O.sub.3, whereby aluminium oxide is reduced with aluminium metal to give gaseous aluminium and aluminium sub-oxides (AlO, Al.sub.2O) at temperatures where the partial pressure of combustible gases exceeds 0.1 atmosphere, whereby the pool of reactant is molten aluminium oxide kept at temperatures above the melting point thereof, whereafter gaseous aluminium and the sub-oxides are oxidized above the molten aluminium oxide bath to aluminium oxide which is captured in a filter.

(4) The main reaction for forming the sub-oxide will be:
Al.sub.2O.sub.3+4Al=3Al.sub.2O (g)
Al.sub.2O.sub.3+Al=3AlO (g)

(5) This method is thus an aluminothermic process.

(6) As indicated above, aluminium oxide and aluminium metal are added to the molten bath of aluminium oxide. Preferably the aluminium oxide and aluminium are injected into the molten pool of aluminium oxide, and the resulting aluminium vapours and aluminium sub-oxide gases are combusted immediately after production in the bath.

(7) In one embodiment the pool of aluminium oxide comprises 20-50 weight % aluminium oxide and 50-80 weight % zirconium dioxide. In another embodiment the pool of aluminium oxide comprises 30-55 weight % aluminium oxide and 45-70 weight % zirconium dioxide.

(8) In a molten pool having the above-indicated compositions, the molten pool will have a higher temperature than a molten pool consisting of aluminium oxide only; see e.g., G. Cervales, Ber. Deut. Keram. Ges., 45 [5] 217 (1968) for a phase diagram for the system Al.sub.2O.sub.3—ZrO.sub.2 showing that the melting point of the compositions described above is higher than for pure aluminium oxide. This will provide a faster reaction when aluminium oxide and metallic aluminium are added to the pool. Thus, a higher productivity of aluminium oxide particles is achieved. Zirconium dioxide in the molten pool will be inert and will not contaminate the aluminium oxide particles.

(9) In the method for producing spherical submicron particles of aluminium oxide, the reaction of aluminium oxide and aluminium will, as indicated above, give primarily aluminium sub-oxides at temperatures above the melting point of aluminium oxide and at temperature where the partial pressure exceed a certain level. As illustrated in FIG. 1, the partial pressure of aluminium sub-oxide, Al.sub.2O, reaches 0.1 atmosphere at 2200 K and thereafter increases rapidly with increasing temperature. From the curve it is seen that the vapour pressure of Al.sub.2O by the reaction starts to become significant at temperatures above approximately 2000° C. (2273K). The pool of molten aluminium oxide is kept at temperatures above the melting point of aluminium oxide, preferably at significantly higher temperature. The reactants are brought into contact with the molten pool of aluminium oxide by injection or other suitable means, and the resulting aluminium vapour and aluminum sub-oxides gasses are combusted by air or oxygen immediately after formation. By this combustion spherical and essentially submicron aluminium oxide particles are obtained.

(10) The process for the preparation of aluminium oxide may be carried out in conventional or modified electrical furnaces for the preparation of fused alumina (brown fused alumina or white fused alumina). Such furnaces exist in different embodiments, known as for instance Higgins furnaces or tilt furnaces, as well as other designs. The typical furnaces will consist of a cylindrical shell of steel equipped with an inner lining of refractive material and an outer water cooling. The energy is provided using graphite or carbon electrodes arranged in a triangular arrangement. The furnace effect may typically be about 1-10 MW. Around the electrodes an open bath may be provided to which metallic aluminium and aluminium oxide may be added. Aluminium may be added in the form of chunks; however, the addition of liquid aluminium may also be envisaged. Aluminium has a lower density than molten alumina, and will therefore exist as a layer on the top of the pool.

(11) The method for the production of alumina can thus be carried out in existing process equipment. In addition a filter will be needed for containing the produced alumina. If desired the off gases from the filter may comprise a simple cleaning facility for NO.sub.x, according to the state of the art.

(12) The problem connected with the combustion of liquid aluminium is that a high temperature is necessary to provide ignition (according to our experiments about 1600-1700° C.). Further, it is difficult to maintain the combustion due to oxide (scull) formation. It is also assumed that the reaction proceeds via the gas phase where the first step is endothermic. Thus energy must be supplied continuously to avoid cooling of the aluminium oxide melt and thereby extinguishing of the process. This is possible in a melting furnace with electrodes. Even if the gross reaction Al+O.sub.2.fwdarw.Al.sub.2O.sub.3 is strongly exothermic, the heat of combustion is formed a distance above the pool, and may not be available down in the melt.

(13) The pool or bath of molten aluminium oxide (about 2050 degrees C. or more) will serve as a heat buffer for stabilizing and facilitate the process.

(14) The process according to the invention may be carried out using relatively inexpensive raw materials (calcined alumina and metallic aluminium). Compared to other processes this makes it possible to prepare affordable products. This is a decisive factor for high volume uses, such as for refractory materials.

(15) The process for the preparation of spherical, submicron particles of aluminium oxide is aluminothermic and thus the disadvantages of carbothermic processes are avoided, such as the formation of carbides and oxycarbides.

(16) The use of pure raw materials, such as high grade alumina, high purity aluminium and electrodes made of high-purity graphite makes it possible to produce high purity qualities of submicron/nanoalumina. This opens up a range of uses such as high-performance structural ceramics, advanced polishing agents such as for semiconductors, raw material for the preparation of optical and functional ceramics, bioceramics and so forth.

(17) Having described preferred embodiments of the invention it will be apparent to those skilled in the art that other embodiments incorporating the concepts may be used. These and other examples of the invention illustrated above are intended by way of example only and the actual scope of the invention is to be determined from the following claims.