JPH06116773A - Method for recovering aluminum from foil scrap - Google Patents

Abstract

PURPOSE:To obtain metal aluminum with a high recovery rate from foil scrap, such as chemical conversion foil, etching foil and plane foil. CONSTITUTION:Aluminum foil scrap 30 which is taken up to a coil form or is press-formed to a lump shape is placed on a top plate 14 and is preheated by the radiation heat from a fused salt electrolytic furnace 10, by which moisture is removed therefrom. The foil scrap 30 after the preheating is pushed into a fused salt 20 from an electrolytic bath surface exposed by pushing crusts 26 and alumina 21 into the electrolytic bath and melting the crusts and the alumina. The metal aluminum-component in the foil scrap settles in the fused salt 20 and is sent into a metal pool 22. The aluminum in a compd. state of an oxide, etc., is electrolytically reduced to a metal state and is sent into the metal pool 22. As a result, the oxide, etc., are also consumed as a recovery source and, therefore, the metal aluminum is recovered with the high recovery rate.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for recovering aluminum as molten metal from aluminum foil scrap.

[0002]

2. Description of the Related Art Aluminum is produced by subjecting raw materials such as bauxite to electrolysis using molten salt, but the power consumption is very high. Considering effective use of resources and environmental issues, it is also considered to recycle and use used aluminum in order to reduce power consumption. In order to reuse aluminum, it is a general method to dissolve aluminum scrap in a heating furnace, elute metallic aluminum, and recover it as an aluminum ingot. Also,
Japanese Patent Application Laid-Open No. 60-208491 discloses that aluminum scrap is supplied to a molten salt bath and molten metal aluminum is collected by filtration with a ceramics filter. The molten aluminum metal obtained is then sent to a scouring electrolytic cell.

[0003]

As resources that are recovered as valuable metals, there are foil scraps such as chemical conversion foils, etching foils and plain foils. When chemical foil scrap is used as a recovery raw material, after pressing the foil scrap into a block,
Aluminum is recovered as a molten metal by heating to 700 ° C. in a heating furnace. However, the yield at this time is only about 20%. Although aluminum metal is recovered from the etching foil in the same manner, the yield of the etching foil having a thickness of, for example, about 70 μm being metallic aluminum is about 60%. The yield of recovering metallic aluminum from the same plain foil is less than 60%.

Such a low recovery rate from foil scrap is due to the fact that an oxide film or the like is formed on the foil surface and the ratio of metal present in the scrap is low. For example, in anodized chemical conversion foil, the metal content may be 50% or less of the foil, depending on the thickness of the foil. Moreover, since it is a metal with a large oxygen affinity and is in a foil state with a large specific surface area, it is easily oxidized during the process of heating and melting the foil scrap in the heating furnace, becoming alumina and reducing the recovery rate of metallic aluminum. Let
The oxidized and burned aluminum remains as an undissolved slag, catching the dissolved metallic aluminum. This also reduces the recovery rate of metallic aluminum. Furthermore,
The oxide film on the foil surface slows the dissolution of foil scrap and reduces productivity.

JP-A-60-2084 using a molten salt bath
According to the method disclosed in Japanese Patent No. 91, although the elution and recovery of aluminum from scrap is smoothly performed, the aluminum content present in scrap as oxides or the like which is not in a metallic state is not recovered. Therefore, the recovery rate is still low. The present invention has been devised in order to solve such a problem, and dissolves and recovers the metallic aluminum content present in the scrap and at the same time converts the aluminum content in the combined state such as oxides into the metallic state. The purpose is to recover metallic aluminum from foil scrap at a very high recovery rate by electrolytic reduction into.

[0006]

In order to achieve the object, an aluminum recovery method of the present invention is to electrolyze aluminum foil scrap wound into a coil or aluminum foil scrap pressed into a block into a molten salt electrolysis furnace. It is characterized in that it is pushed into a bath, the aluminum oxide content is dissolved in an electrolytic bath, and then electrolyzed, and is recovered as molten metal aluminum together with the metal aluminum content in the foil. As the electrolytic bath, it is preferable to use a fluoride system having a large ability to dissolve oxides. In addition, since the amount of boron charged in the electric smelting furnace is controlled according to the amount of foil scrap that has been subjected to chemical conversion treatment using boric acid, an Al-B alloy with the specified components and composition is used. It is also possible to manufacture.

[0007]

[Operation] In the present invention, for example, a molten salt electrolysis furnace 10 shown in FIG. 1 is used. The molten salt electrolysis furnace 10 includes a furnace body 13 and a cathode carbon 12 connected to a cathode bus bar 11.
It is located at the bottom of. The furnace body 13 is constructed of a refractory material having excellent heat resistance and heat insulation properties, and has a top plate 14 at the upper portion. The anode carbon 15 is arranged so as to face the cathode carbon 12, and is connected to the anode 16. Inside the furnace body 13, a molten salt 20 is charged between the cathode carbon 12 and the anode carbon 15. The surface of the molten salt 20 is covered with alumina 21. The aluminum oxide (alumina) dissolved in the molten salt 20 is electrolytically reduced by the electric current flowing between the cathode carbon 12 and the anode carbon 15. Metallic aluminum produced by electrolytic reduction is contained in molten salt 20 as cathode carbon 1.
2 is settled on to form a metal pool 22. Furnace body 13
A crust 25 formed by mixing and solidifying the electrolytic bath and alumina is formed on the inner wall surface of the. Molten salt 20 and alumina 21
A similar crust 26 is also formed at the interface with.

The foil scrap to be reused as a source of aluminum is placed on the top plate 14 as a foil scrap 30 which is coiled or pressed into a block, and is preheated by radiant heat from the molten salt electrolysis furnace 10. To be done. Thereby, the water contained in the foil scrap 30 is removed. In addition, using a separate heating furnace for preheating, the foil scrap 30 is kept at a high temperature of 100 ° C. or higher,
It is also possible to appropriately take out the preheated block foil scrap from the heating furnace and put it in the molten salt electrolysis furnace. When the preheated foil scrap 30 is charged into the electrolytic bath, the alumina 21 and the crust 26 covering the bath surface are pushed into the electrolytic bath and melted to expose the electrolytic bath surface. Then, using the pushing tool 31, the exposed temperature is about 980 ° C.
The foil scrap 33 is gradually pushed into the molten salt 20 from the bath surface 32 of the following electrolytic bath. It is preferable to add fresh alumina at the same time when the foil scrap 33 is charged.
The fresh alumina suppresses heat radiation from the electrolytic bath by covering the surface of the electrolytic bath, and also prevents a part of the pressed foil scrap 33 from being exposed on the surface of the electrolytic bath and being oxidized by contact with outside air. In the present invention, since the oxide in the foil scrap is replenished as alumina, it is possible to reduce the amount of fresh alumina used as compared with the usual aluminum molten salt electrolysis.

During the process of pushing the foil scrap 33, the foil scrap 33 melts into the molten salt 20 without the surface thereof being oxidized by the molten salt 20. At this time, the alumina content such as aluminum oxide treated in the fluoride bath is
It has a higher dissolution capacity than when treated with a chloride bath. In this respect, in order to further improve the recovery rate, treatment with a fluoride bath is preferred. The metal content of the pressed-in foil scrap 33 is directly settled and enters the metal pool 22 at the bottom of the furnace together with the molten aluminum produced by the electrolysis of the molten salt 20. Aluminum in the combined state such as aluminum oxide undergoes electrolysis by molten salt electrolysis and is reduced to the metallic state. For example, aluminum oxide undergoes the same decomposition reaction as electrolysis of alumina as described below, and is recovered as metallic aluminum. Al ₂ O ₃ → 2Al ↓ + 3 / 2O ₂ O ₂ + C → CO ₂ ↑

That is, in the conventional recovery of aluminum from foil scrap, the recovery rate is very low at about 30% because only the metal content excluding the aluminum content in the combined state of oxides and the like is targeted for recovery. On the other hand, in the present invention, the aluminum component in the combined state such as oxides is also electrolyzed and recovered in the metallic state. As a result, the oxide film in the foil scrap and the reoxidized aluminum are also used as resources, so that metallic aluminum can be obtained with a very high recovery rate.

[0011]

【Example】

Example 1: (Chemical Foil) As the molten salt electrolysis furnace 10, a horizontal electrolysis furnace having a rated current of 55 kA was used to prepare a molten salt 20 containing 85% cryolite, 5% aluminum fluoride and 10% calcium fluoride. . Molten salt 2
0 means 2 between the cathode carbon 12 and the anode carbon 15.
The temperature was maintained at 970 ° C. by supplying electric power of 50 KW. As the foil scrap, a chemical conversion foil having an average thickness of 70 μm was used. This conversion foil contains 70% of aluminum in the metallic state and γ-alumina (Al ₂ O ₃ · H ₂ O).
The aluminum content was 30%. Winding the formed foil into a coil with an inner diameter of 50 mm, an outer diameter of 200 mm and a height of 500 mm.
0 was prepared. The foil scrap that cannot be formed into a cylindrical shape is 100 mm high, 250 mm long and 500 mm wide.
Was pressed into a rectangular parallelepiped shape.

Each of the foil scraps 30 was held on a wooden pallet, and a daily charge of 150 kg was prepared. A wooden pallet is placed on the top plate 14 of the molten salt electrolysis furnace 10 three times a day at a rate of 50 kg,
Left for hours. The foil scrap 30 is used in the molten salt electrolysis furnace 10
Preheated by heat radiation from the
The temperature was raised from 0 ° C) to 200 ° C. In this preheating step, the water contained in the foil scrap 30 was completely removed.

The foil scrap 30 which has been preheated is melted from the electrolytic bath surface 32 exposed by breaking the crust 26.
I pushed it into 0. By introducing the foil scrap 33,
There was an increase in the production of aluminum metal obtained by electrolytic smelting. It was estimated that the increase was derived from the foil scrap 33, and the recovery rate of metallic aluminum from the foil scrap 33 was calculated. The obtained recovery rate was 80%. This recovery rate is higher than the aluminum content (70%) contained in the foil scrap in the metallic state, which means that the aluminum content in the Al ₂ O ₃ state was electrolytically reduced and also collected.

Example 2 (Etching foil) An etching foil having an average thickness of 70 μm was used as foil scrap. This etching foil does not have an oxide film formed on the surface thereof, and is an aluminum resource of substantially 100% purity. The foil scrap was pressure-molded into a lump foil scrap in the same manner as in Example 1, and was placed in a molten salt electrolysis furnace under the same conditions as in Example 1. The recovery rate in this case was 95%.

Example 3: (Plain foil) As the foil scrap, a plain foil having an average thickness of 70 μm was used. This plain foil has a thickness of 0.5 μm γ-
Two alumina layers were formed, and the aluminum content in the metallic state was 98.9%. The foil scrap was pressure-molded into a lump foil scrap in the same manner as in Example 1, and was placed in a molten salt electrolysis furnace under the same conditions as in Example 1. The recovery rate in this case was 93%. Further, in all of Examples 1 to 3, there was no change in the recovery as metallic aluminum even when the foil scrap was continuously added, and the high recovery rate was maintained.

Comparative Example: (Melting of Foil Scrap by Heating Furnace) The foil scrap was heated to 700 ° C. in a heating furnace to elute the metal aluminum content and collect it as an aluminum ingot. As the foil scrap to be heated and melted, the one that was pressure-molded into a lump like the example 1 was used. The recovery rates in this case were as follows. Foil type Metal Al recovery rate Chemical conversion foil 70% 20% Etching foil 100% 60% Plain foil 98.9% 80%

As is apparent from this contrast, the examples according to the invention obtain a very high recovery of metallic aluminum from foil scrap. This is because aluminum components such as oxides are reduced to a metal state by molten salt electrolysis,
It comes from being recovered as metallic aluminum. In addition, the fact that the aluminum is suppressed from being oxidized and consumed in the process until the foil scrap is melted in the molten salt is also a cause of the high recovery rate.

Example 4: (Influence of boride treatment) A chemical conversion foil having a composition of 71% metallic aluminum and 29% γ-alumina and having a thickness of 70 μm was used as a scrap material. The chemical conversion foil was manufactured by anodic oxidation in a boric acid conversion treatment solution at 93 ° C. 0.3% of boric acid in terms of B was attached to the surface of the chemical conversion foil. The formed foil after the boric acid treatment was placed in a fluoride bath of a melting electrolysis furnace in the same manner as in Example 1 for 3 days a day.
I put it in twice. The input amount was set to 50 kg for each process. When the foil scrap was subjected to molten salt electrolysis in this manner, an aluminum melt having the following composition was obtained. The recovery rate of metallic aluminum from the foil scrap was 80%. Composition of the obtained aluminum melt Al: 99.88% by weight Cu: 0.003% by weight Si: 0.04% by weight B: 0.04% by weight Fe: 0.04% by weight

[0019]

As described above, in the present invention, foil scrap as a recycling resource is put into a molten salt electrolysis furnace to recover metallic aluminum. Of the foil scraps charged into the furnace, the metal aluminum content is settled as it is into the molten salt and sent to the metal pool.
Aluminum compounds in a combined state such as oxides are reduced to a metal state by molten salt electrolysis and sent to a metal pool. Therefore, aluminum oxide or the like contained in the foil scrap is also consumed as a recovery source, and metallic aluminum is recovered at a high recovery rate.

[Brief description of drawings]

FIG. 1 shows an example of a molten salt electrolysis furnace used in the present invention.

[Explanation of symbols]

10 Molten salt electrolysis furnace 14 Top plate
20 Molten Salt 22 Metal Pool 30 Foil Scrap 32 Exposed Electrolyte Bath Surface 33 Stamped Foil Scrap

Front page continuation (72) Inventor Shuichi Asakono 161 Kambara, Kambara-cho, Awara-gun, Shizuoka Inside Nippon Light Metal Co., Ltd. Kambara Electrolysis Plant (72) Inventor Kenichi Kanno 161 Kambara-electrolyte, Kanbara-cho, Awara-gun, Shizuoka Nippon Light Metal Co., Ltd. (72) Inventor Masatoshi Nanba 3-13-12 Mita, Minato-ku, Tokyo Within Japan Light Metals Co., Ltd.

Claims (3)

[Claims] 1. An aluminum foil scrap wound into a coil or an aluminum foil scrap pressure-molded into a lump is pushed into an electrolytic bath of a molten salt electrolysis furnace, and the aluminum oxide component is dissolved in the electrolytic bath and electrolyzed to obtain a foil. A method for recovering aluminum from foil scraps, characterized in that it is recovered as molten metal aluminum together with the medium metal aluminum content. 2. A fluoride-based electrolytic bath is used.
The aluminum recovery method described. 3. The method for recovering aluminum according to claim 1, wherein the aluminum foil scrap is treated with boric acid.