KR20030074492A - manufacture method for aluminum chip and Powder from aluminum dros - Google Patents

Abstract

PURPOSE: A manufacturing method of aluminum chip and powder from aluminum dross is provided to change slag into aluminum for deoxidation by manufacturing metal aluminum chip and powder produced in the milled and classified state without melting process differently from an existing aluminum dross treatment method. CONSTITUTION: In a recovery method of metal aluminum through retreating process of aluminum dross, the manufacturing method of aluminum chip and powder from aluminum dross comprises the processes of preparing aluminum chip and aluminum powder per 90% or more of respective particle sizes (standard mesh size) from the aluminum dross; using the prepared aluminum chip and aluminum powder as raw material of aluminum chip for slag deoxidizer; milling aluminum oxide into ultra fine particles of micron unit from the aluminum dross; and removing aluminum oxide by colliding aluminum oxide included in metal aluminum of the aluminum dross with dross particles, thereby inducing deformation of metal aluminum.

Description

Manufacturing method for aluminum chip and powder from aluminum dross

When aluminum metal or aluminum scrap is dissolved, an oxide layer called dross is formed on the surface of the molten aluminum because aluminum is a well-oxidized metal. The amount of dross generated during dissolution depends on the working temperature, dissolution method and components of the dissolution scrap, and is generated in the melting furnace and the flow path of the aluminum molten metal when it is poured into the mold.

Aluminum dross can be divided into white dross, black dross, and salt cake.In the case of white dross, after dissolving aluminum, before pouring molten metal into the mold, Refers to the aluminum oxide formed on the surface of the molten metal. White dross contains a large amount of aluminum metal, so that aluminum can be recovered to about 60 to 70% of the dross weight. In the case of black dross, the flux is added to prevent the oxidation of the molten surface and to improve the separation efficiency of impurities in the molten metal. It contains aluminum metal. Salt cake refers to dross remaining after recovering aluminum metal after redissolved by mixing black dross and salt (salt (NaCl + KCl)), and less than 7 ~ 8% in salt cake Since aluminum is present, most of it is landfilled or discarded.

The three types of dross generated during the melting of aluminum are divided into aluminum and aluminum oxide through preliminary treatment such as crushing and classification before melting to increase the recycling rate and recovery rate of aluminum metal. The larger is the presence of a lot of aluminum metal, the smaller the particle size is a lot of aluminum oxide. Through this pretreatment process, the aluminum oxide in the dross is separated, the amount of dross to be dissolved in the dross is reduced, and the aluminum metal content is increased to melt the aluminum ingot (Rotary, Crucible, Reflector, etc.). In this case, aluminum oxide with less than 5-10% of the amount of aluminum metal generated is buried, and in some cases, the aluminum content of the discarded aluminum dross is increased to be applied as a heat insulating material of steelmaking line.

Figure 1 shows the process of the existing apparatus for processing aluminum dross. The aluminum dross processing apparatus is a method of manufacturing aluminum ingots in a melting furnace by removing aluminum oxide through crushing and classification process and increasing the aluminum content. Because of this considerable amount, the recovery rate of aluminum metal is reduced, so that aluminum present in the dross cannot be completely recovered, but rather the amount of dross to be disposed of or buried is increased by making aluminum oxide which is not recovered in the dross into aluminum oxide. I'm making it.

Therefore, in the present invention, to increase the recovery rate of the metal aluminum in the aluminum dross and to reduce the amount of aluminum oxide generated, the conventional aluminum dross treatment which is subjected to the dissolution process after crushing and classifying according to the particle size from the existing aluminum dross. Unlike the method, the slag was made of aluminum for deoxidizer by manufacturing metal aluminum chips and powders that can be commercialized in a crushed and classified state without going through a dissolution process.

Since the pretreatment process of aluminum dross focuses on the manufacturing method of ingot in aluminum melting furnace, the classification of metallic aluminum present in dross was not sufficiently performed during the crushing and classification process. Increasing the amount of flux increased the recovery of metal aluminum, but also increased the amount of aluminum oxide to be disposed of or landfilled due to the effect of oxidation of metal aluminum and aluminum oxide that could not be removed during the secondary melting process. .

The present invention is a method of minimizing the amount of aluminum oxide to be disposed and landfilled compared to the existing treatment method, and does not produce aluminum ingots, which are expensive to manufacture from aluminum dross. It is a technology that does not cause environmental pollution because it completely eliminates the amount of wastes, and only aluminum metal is recovered from the aluminum dross to be disposed of without producing additional aluminum oxide. Achievement is expected to contribute greatly to cost reduction and productivity improvement.

Figure 1: An embodiment of an existing device

Figure 2: An embodiment of the present invention

Figure 3: An embodiment of the present invention

In the present invention, to recover the metal aluminum from the aluminum dross, the metal content of pure metal aluminum in the aluminum dross generated after the aluminum dissolution process was measured. The alloying elements contained in the aluminum dross depend on the aluminum alloy component of the aluminum melting line as shown in [Table 1]. The higher the alloying, the more significant amounts of heterometals other than Al were included.

The aluminum dross produced by each of the above melting companies having the component elements shown in Table 1 was crushed and classified by an existing aluminum pretreatment apparatus. When the aluminum dross is impacted, the metallic aluminum is ductile due to mechanical impact, so the shape is modified in a direction to alleviate the impact. Aluminum oxide is broken into fine sizes by mechanical impact and the amount of impact is increased. It was crushed to a smaller particle size and ultimately classified into two types of metal aluminum and finely divided aluminum oxide in the aluminum draw.

Table 2 shows the size of recoverable metal aluminum in the present invention to observe the size distribution of black dross remaining after recovering aluminum after primary treatment of white dross in a melting company. Standard meshes were used to classify them into 20, 50, 80, and 100 meshes. As a result of the classification treatment of the present invention, the proportion of dross having a particle size capable of recovering metallic aluminum was about 34%.

In the present invention, in order to know the aluminum recovery rate by particle size of the sorted dross, aluminum recovery was measured by adding a predetermined amount of aluminum dross and a flux (NaCl + KCl) used for dissolving aluminum. Aluminum recovery rate is the amount of oxidized and removed (about 95%) of the seeded aluminum (I _s ) initially charged to form the aluminum molten metal from the weight of the ingot cast (I _f ) after melting. Calculated as a ratio to the amount (D). In addition, in the dross of 80 mesh or less, metal recovery was measured while varying the amount of flux (NaCl + KCl) in order to observe the possible amount of aluminum metal recoverable.

[R] aluminum recovery

[D] dross charge

[I _f ] Ingot weight recovered from aluminum

[I _s ] Ingot for seed to make initial molten metal

[Table 3] shows the amount of aluminum recovered by changing the amount of flux in the aluminum dross. Metal aluminum could not be recovered without increasing the amount of flux. In order to increase the recovery rate, the increase of flux leads to an increase in manufacturing cost, and thus it is found that it is inefficient to recover metal aluminum from aluminum dross having a small particle size. Aluminum dross, which has a relatively large particle size, was also converted to aluminum oxide when measuring recovery rate. Therefore, when aluminum dross is treated by the conventional method, it is found that the processing of waste resources is inefficient because aluminum oxide is formed during melting. .

Therefore, in the present invention, unlike conventional treatment method, aluminum metal is separated by dissolving aluminum dross and the metal and oxide generated from aluminum dross after the preliminary pretreatment of metal aluminum and aluminum oxide by crushing and classification. The aluminum dross having a low content of 80 mesh or less was used as a raw material for steel insulation and ceramic products, and the secondary treatment was performed to increase the amount of metallic aluminum of a predetermined size or more separated from the aluminum dross.

Aluminum dross over a certain size contains aluminum oxide and molten residue on the surface and inside of metal aluminum, which have lower fracture strength than metal and are weak to mechanical impact, and these aluminum oxides are re-crushed into fine powder by fine grinding and crushing. The aluminum oxide contained in was separated, leaving only dross having a high metal aluminum content.

In the present invention, after crushing and size classification of 1000 g of aluminum dross of +80 mesh or more, the amount of metal aluminum by particle size and the aluminum oxide removal efficiency according to the crushing were measured. [Table 4] shows the results of the reclassification after the first crushing treatment and classification. The weight ratio of metal aluminum was high in the dross having a large particle size, and the dross having a small particle size before crushing was pulverized with aluminum oxide at the time of crushing. As a result, the amount of metallic aluminum mixed in the aluminum dross after crushing was significantly reduced. From this, it can be seen that when the aluminum dross is repeatedly crushed, aluminum oxide and dissolved residues existing on the surface and inside of the metal aluminum are pulverized and the metal content of the aluminum dross from which the aluminum oxide is removed increases. It could be determined that aluminum chips and powders having an aluminum content of 90% or more were prepared without undergoing a long dissolution process.

However, in order to manufacture more than 90% of aluminum chips and powders from the aluminum dross in which fine aluminum oxide is inherent, aluminum oxide present in the metal aluminum must be completely removed in addition to the crushing of the aluminum dross. In order to increase the metal aluminum content in the aluminum dross, the particle size of aluminum oxide can be crushed to micron level by causing interparticle and wall impact by air (Roller Mill, Ball Mill, Rod Mill, Air classified Mill). , Air jet mill, steam jet mill, etc.) was charged with aluminum dross and crushed aluminum oxide and aluminum metal were buoyed by air and the two raw materials were separated by specific gravity. In addition, to recover the metal aluminum crushed together with aluminum oxide, an air separator (floating separator, gravity separator, etc.) is installed to separate the metal aluminum from the aluminum oxide to increase the recovery rate of the metal aluminum from the aluminum dross and in the metal aluminum By removing the inherent aluminum oxide, metal aluminum chips and powders having an aluminum content of 90% or more could be prepared from aluminum dross.

[Table 5] shows the weight ratio of aluminum dross by weight and aluminum content by particle size after crushing 1000 g of raw material of 80 mesh or more with the apparatus of the present invention. The metal content of metal aluminum except aluminum oxide is determined in each particle size distribution. All have 90% or more of aluminum and can be applied to products using aluminum chips and powder.

FIG. 2 is a process for manufacturing aluminum chips and powder using aluminum dross in the present invention, which is mainly processed by an aluminum melting company using aluminum dross. After charging the vibrating screen and classifying the particle size, the fine oxide was sucked into the dust collector and subjected to rough crushing treatment to increase the content of metallic aluminum in aluminum dross over a certain size. At this time, the coarse aluminum dross is crushed to a uniform size and the aluminum oxide in the aluminum dross is primarily crushed and discharged to the classifier. In the classifier, aluminum oxide below a certain size is classified by a dust collector, a rotating mesh, and a vibration screen, and only aluminum dross having a high metal aluminum content is introduced into the pulverizer.

The pulverizing apparatus of the present invention is an apparatus capable of crushing aluminum oxide to a size of micron or less to remove aluminum oxide and dissolved residues attached to the inside and the surface of metallic aluminum in aluminum dross. The grinding method used in the pulverization apparatus is a method of collision of aluminum dross particles and a collision of aluminum dross particles with a high speed and force on the wall of the grinder. In addition, since the metal aluminum is ductile, deformation occurs, and the aluminum oxide present in the inside and the surface of the metal aluminum causes the peeling effect due to the impact and the deformation of the metal aluminum, thereby increasing the metal aluminum content in the aluminum dross. The crushed aluminum oxide is sucked by the dust collector, and the remaining aluminum dross having a high content of metal aluminum is classified by size by a particle size classifier to produce aluminum chips and powder. 3 is a step in which the coarse crushing apparatus is omitted from the existing pretreatment apparatus, and the same aluminum chip and powder as in the above-described process may be manufactured even when the apparatus of the present invention is used in the coarse crushing apparatus.

According to the existing aluminum dross pretreatment method, the aluminum recovery rate was less than 70% because the aluminum oxide and the metal aluminum in the aluminum dross were not completely separated, and the metal aluminum which was not separated was used in the furnace using flux. Because of the high recovery cost, the production cost is high, and aluminum oxide is generated even during the dissolution process for producing aluminum ingots, resulting in low aluminum recovery. However, applying the technology of the present invention can be separated from the aluminum dross to include more than 90% metallic aluminum content can increase the aluminum recovery in the aluminum melting process. In addition, it is possible to commercialize the aluminum chip and powder produced in the present invention without dissolution process can increase the amount of metal aluminum used by more than 20% than the existing aluminum dross pretreatment apparatus, not only to increase the metal recovery rate from waste resources but also to improve productivity, Cost reduction and environmental pollution have been greatly reduced.

Claims (5)

In the method of recovering the metal aluminum through the reprocessing of aluminum dross, Manufacturing an aluminum chip and an aluminum powder from the aluminum dross at a particle size (standard mesh size) of 90% or more; Using the prepared aluminum chip and aluminum powder as a raw material of the aluminum chip for slag deoxidizer; Crushing aluminum oxide from the aluminum dross into ultra-fine particles in microns; Manufacture of aluminum chips and powders from aluminum dross comprising aluminum oxide embedded in the metal aluminum of the aluminum dross and removing aluminum oxide by inducing deformation of metal aluminum by collision of aluminum dross particles. Way. The method of claim 1, wherein a roller mill, an air jet mill, and a steam jet mill are used to simultaneously apply mutual impact and mechanical impact of the aluminum dross particles. The method for producing aluminum chips and powders from aluminum dross according to claim 1, wherein the porous metal aluminum and powder from which aluminum oxide is removed from the aluminum dross are manufactured. The method of claim 1, wherein the porous metal aluminum and powder from which the metal aluminum is removed from the aluminum dross are manufactured. The method for producing aluminum chips and powders from aluminum dross according to claim 1, wherein the aluminum oxide is continuously removed by pulverization alone and metal aluminum chips and powders are produced.