JP2023063362A - Noble metal recovery method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a noble metal recovery method that can reduce recovery loss of noble metal from recycling raw materials.

SOLUTION: A noble metal recovery method includes putting recycling raw material 30, with sulfide, into a melting furnace 1, forming a mat layer 13 and a slag layer 14 in the melting furnace 1, and sedimenting noble metal in the recycling raw material 30 within the melting furnace 1 and absorbing it onto the mat layer 13.

SELECTED DRAWING: Figure 1

COPYRIGHT: (C)2023,JPO&INPIT

Description

The present invention relates to a method for recovering precious metals.

Recycled raw materials generally include precious metals such as gold (Au), silver (Ag), platinum (Pt), and palladium (Pd) in addition to copper and zinc. Recovery of these valuable metals is also important from the viewpoint of resource conservation through resource recycling.

Conventionally, various researches and developments have been made as methods for recovering valuable metals from recycled raw materials. For example, Japanese Unexamined Patent Application Publication No. 2017-120132 (Patent Document 1) discloses a molten material generated by heating and melting an object to be processed inserted into a melting furnace. A slag tap method is described for separating matte and slag at a section and withdrawing the obtained slag out of the furnace.

JP 2017-120132 A

The invention described in Patent Document 1 can obtain a predetermined effect as a method for extracting slag without causing the slag to overflow from the slag trough by preventing the outflow of unmelted material when extracting slag from the melting furnace. ing. However, the invention described in Patent Document 1 is an invention relating to the configuration of a melting furnace, and there is still room for investigation from the viewpoint of a processing method using a melting furnace.

When processing recycled raw materials using a melting furnace, valuable metals contained in the recycled raw materials become metal-like substances or oxides in the melting furnace, are then reduced, and are absorbed into the mat layer. However, depending on the treatment conditions, the noble metal may be absorbed into the slag layer (entanglement) side, and as a result, loss of recovery of the noble metal may occur.

Therefore, the present disclosure provides a method for recovering precious metals that can further reduce recovery loss of precious metals in recycled raw materials.

In one aspect of the method for recovering precious metals according to the embodiment of the present invention, a recycled raw material is put into a melting furnace together with a sulfide, a matte layer and a slag layer are formed in the melting furnace, and A method for recovering precious metals is provided in which the precious metals are allowed to settle in the melting furnace and absorbed into the matte layer.

According to the embodiment of the present invention, it is possible to provide a method for recovering precious metals that can further reduce recovery loss of precious metals in recycled raw materials.

BRIEF DESCRIPTION OF THE DRAWINGS It is sectional drawing which shows an example of the melting furnace which can be utilized for the recovery|recovery method of the noble metal which concerns on embodiment of this invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. It should be noted that the embodiments shown below are examples of devices and methods for embodying the technical idea of the present invention, and the technical idea of the present invention is based on the structure, arrangement, etc. of the component parts as follows. It is not specific.

Before describing the method of recovering precious metals according to the embodiment of the present invention, a melting furnace 1 suitable for the method of recovering precious metals according to the embodiment of the present invention will be described using the example of FIG. FIG. 1 is merely an example, and the present embodiment is of course not limited to the configuration of the melting furnace 1 shown in FIG. 1 as long as the furnace is capable of forming the slag layer 14 and the mat layer 13 is.

For example, melting furnaces such as tilting reverberatory furnaces, shaft furnaces with a hearth, oval furnaces, drum furnaces, and top-blown converters that can directly refining blister copper (black copper, etc.) also relate to the present embodiment. It can be used as a melting furnace 1.

As shown in FIG. 1, the melting furnace 1 can be based on a reverberatory furnace, which is one of horizontal furnaces. The inside of the melting furnace 1 is mainly made of basic heat-resistant bricks 10 such as magnesite and chromium-magnesite.

A burner 15 is arranged at one end of the melting furnace 1 . The burner 15 blows out a long flame 16 into the furnace by burning fuel such as heavy oil, waste oil, or natural gas. A plurality of charging ports 11 for charging the raw material 30 into the melting furnace 1 are provided side by side in the upper portion of the melting furnace 1 .

The raw material 30 charged from each charging port 11 is directly melted by the flame 16 when settling toward the hearth of the melting furnace 1 located below the charging port 11, or is reflected by the ceiling or inner wall. melted by the heat generated. On the hearth, the raw material 30 is deposited as deposits 40 and heated to form a melt 41 .

At the bottom of the melting furnace 1, at a position away from the burner 15, a furnace floor for depositing deposits 40 to form a melt 41 is continuous with and deeper than the furnace floor. A hot water pool portion 18 is formed. An inclined surface is formed between the hearth portion and the hot water pool portion 18 .

The molten material 41 melted by the flame of the burner 15 flows from the hearth along the inclined surface and accumulates in the hot water pool 18 in a molten state. The melt accumulated in the hot water reservoir 18 is separated into a mat layer 13 having a large specific gravity and a slag layer 14 having a smaller specific gravity than the mat layer 13 formed thereon.

Further, an inlet 20 is provided in the ceiling of the melting furnace 1 located above the hot water pool 18, and a ceiling burner (not shown) may be arranged in the vicinity of the inlet 20. An oxygen burner can be used as the ceiling burner. Since the oxygen burner uses oxygen as a combustion-supporting gas for burning fuel, it does not contain nitrogen, which does not contribute to combustion unlike air, so high-temperature combustion is possible.

By supplying fuel such as heavy oil, waste oil and natural gas to the ceiling burner and burning the fuel, a high temperature part of 1500° C. or higher can be locally formed in the melting furnace 1 . The raw material 30 charged from the inlet 20 is melted in the slag layer 14 directly and by the heat reflected from the inner wall of the furnace. Instead of the raw material 30, a sulfide for suppressing recovery loss of valuable metals, especially noble metals, which will be described later, can be introduced from the inlet 20. Alternatively, the sulfide may be supplied together with the raw material through the charging port 11 .

In the melting furnace 1, a matte layer 13 containing 20 to 60% by mass of sulfide is formed. (Tangle) is formed.

In the method for recovering precious metals according to the embodiment of the present invention, for example, using a melting furnace 1 as shown in FIG. and forming a slag layer 14, allowing precious metals contained in the recycled raw material to settle in the melting furnace 1 and be absorbed by the mat layer.

Recycled raw materials include incinerated ash of general household waste, industrial wastes such as asbestos and sludge, parts scraps of electronic and electric products, shredder dust of automobiles, and the like, which are intended for recycling.

Above all, it is a scrap of crushed electronic and electrical equipment such as waste home appliances, PCs and mobile phones. After being collected, it is crushed to an appropriate size and a predetermined sorting process is performed so that the concentration of precious metals in the scrap is concentrated. When electronic and electrical equipment parts scraps subjected to the treatment are used as recycled raw materials, it is advantageous in that a large amount of precious metals can be recovered using a smaller amount of raw materials.

Although it is not limited to the following, electronic and electrical equipment parts scraps include substrates, parts such as ICs and connectors, synthetic resins (plastics) used for housings, etc., wire scraps, metals, film-like parts scraps, Metals, parts, film-like parts scraps, powders, circuit board scraps, parts, etc., which are separated into parts scraps consisting of powders generated by crushing and crushing, and others, and synthetic resins are removed from them, are used as raw materials. By suitably using as, it is possible to increase the efficiency of recovering precious metals with a smaller amount of raw material.

For example, substrate scraps are materials containing synthetic resins and valuable metals. By treating the substrate scraps together with sulfides in the melting furnace 1, the precious metals in the substrate scraps are melted into oxides and then sulfided. It can be reduced by the presence of substances and can be absorbed into the mat layer 13, while the synthetic resin can be melted and oxidized and separated to the slag layer 14 side. It is more effective in that the synthetic resin and valuable metals can be separated more easily.

In order to separate the various scrap parts as described above, it is preferable to perform at least two stages of wind separation and sorting by a metal sorter on raw materials before sorting. The sorting method is not limited to the above. For example, magnetic sorting, sieving, pulverization, eddy current sorting, and sorting by a color sorter can be appropriately combined depending on the material composition and sorting purpose.

The recycled raw material is put into the melting furnace 1 together with the sulfide. The sulfide is not particularly limited as long as it is a substance that can reduce oxides of valuable metals in the recycled raw material, but for example, pyrite (perlite), chalcopyrite (chalcopyrite), copper sulfide ore can be used. Among them, pyrite (FeS ₂ : perlite) is cheaper than chalcopyrite and copper sulfide ore and is easy to secure in quantity. In addition, compared to chalcopyrite and copper sulfide ore, pyrite does not contain copper in itself, so it can absorb and melt more of the copper content of other raw materials that are mixed with pyrite and put into the furnace. By using it, it is possible to reduce the loss of precious metals and improve the recovery efficiency.

When pyrite is charged as sulfide, pyrite is thermally decomposed in the melting furnace 1 according to the following formula (1).
_FeS2 →FeS+1/ _2S2 (1)

Valuable metals including metals such as copper, lead, zinc, and nickel, or precious metals such as gold, silver, platinum, and palladium contained in the recycled raw materials are generated in the melting furnace 1 by thermal decomposition of pyrite according to formula (1). It reacts with the resulting sulfur ( _S2 ) to form metal sulfides. Iron sulfide produced by the pyrite decomposition of pyrite is oxidized to form iron oxide (FeO).

FeO is absorbed into the slag layer 14 and metal sulfides are precipitated and absorbed into the matte layer 13 . At that time, if the valuable metals in the recycled raw material do not sufficiently react with the sulfur (S ₂ ) generated by pyrite pyrite decomposition, these metal oxides will be absorbed into the slag layer 14 side, resulting in metal loss. There is In particular, noble metals such as Au, Ag, Pt, and Pd are desired to reduce loss as much as possible and increase the recovery rate.

According to the method for treating precious metals according to the embodiment of the present invention, valuable metals contained in the recycled raw material, in particular Au, Ag, Pt, Since the precious metal such as Pd can be more reliably absorbed into the mat layer 13 side, loss of the precious metal can be reduced and recovery efficiency can be improved.

As the sulfide to be charged into the melting furnace 1, it is preferable to use, for example, a sulfide having a maximum diameter of 10 mm or less. The amount of sulfide to be added can be appropriately changed according to the composition of the raw material, but it is preferable that the sulfide is added in excess of the content of the valuable metal that migrates to the mat layer 13 .

For example, when copper-containing sludge or the like is charged as a recycled raw material, it is preferable to charge 0.08 kg or more, more preferably 0.09 kg or more, and still more preferably 0.1 kg or more of sulfide per 1 kg of recycled raw material. On the other hand, if the amount of sulfide added is too large, the copper quality of the recovered matte may decrease, or the sulfur oxide (SO _x ) concentration in the exhaust gas may increase. The amount of sulfide fed into the melting furnace 1 can be set to 1 kg or less, further 0.5 kg or less per 1 kg of recycled raw material. This allows the mat layer 13 to more reliably absorb the precious metal contained in the recycled raw material.

It is preferable to convert the copper contained in the recycled raw material into a sulfide by adding sulfide to form the mat layer 13 having a predetermined thickness. By setting the thickness of the mat layer 13 to a certain thickness or more, it is possible to suppress the noble metal from being taken into the slag layer 14 and improve the recovery efficiency of the noble metal.

The thickness of the mat layer 13 formed in the hot water pool 18, that is, the thickness of the mat layer 13 along the vertical direction of the melting furnace 1 is preferably 250 mm or more, more preferably 300 mm or more, further preferably 400 mm or more. is.

The sulfide can be added so that the thickness of the mat layer 13 formed in the hot water pool 18 is 1.5 times, preferably 3 times, and more preferably 6 times or more the thickness of the slag layer 14. preferable. By configuring in this way, loss of precious metals such as Au, Ag, Pt, and Pd in addition to valuable metals such as copper can be suppressed.

After the mat layer 13 is discharged from the melting furnace 1 in a molten state, it is cooled. The mat obtained by cooling is pulverized as necessary and subjected to a predetermined treatment to recover the precious metal contained in the mat. For example, if the matte obtained by cooling is rich in copper or copper sulfide, the matte is sent to a copper smelting process. In the copper smelting process, the matte is put into a flash furnace, undergoes an electrolysis process to produce copper, and the precious metals obtained as electrolytic deposits are sent to a precious metal recovery process and recovered.

According to the present embodiment, the mat layer 13 can more reliably absorb the precious metal contained in the recycled raw material. It can be concentrated.

Although the present invention has been described by the above embodiments, the statements and drawings forming part of this disclosure should not be understood to limit the present invention. That is, the present invention is not limited to the above embodiments, and can be embodied by modifying the constituent elements without departing from the spirit of the present invention. Moreover, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in each embodiment. For example, some components may be deleted from all components shown in the embodiments.

DESCRIPTION OF SYMBOLS 1... Melting furnace 10... Heat-resistant bricks 11... Loading port 13... Mat layer 14... Slag layer 15... Burner 16... Flame 18... Hot water pool 20... Input port 30... Recycled raw material 40... Deposits 41... Molten material

Claims (8)

A recycled raw material is put into a melting furnace together with a sulfide containing pyrite, a mat layer and a slag layer are formed in the melting furnace, and sulfur generated by thermal decomposition of the pyrite reacts with precious metals contained in the recycled raw material. forming a metal sulfide, and allowing the metal sulfide to settle in the melting furnace and be absorbed by the matte layer. 2. The method for recovering precious metals according to claim 1, wherein the matte layer having a predetermined thickness is formed by converting copper contained in the recycled raw material into sulfide by adding the sulfide. 3. The method for recovering precious metals according to claim 2, wherein the thickness is 250 mm or more. The method for recovering precious metals according to any one of claims 1 to 3, wherein the sulfide has a maximum diameter of 10 mm or less. The method for recovering precious metals according to any one of claims 1 to 4, wherein 0.08 kg or more of the sulfide is charged into the melting furnace with respect to 1 kg of the recycled raw material. The method for recovering precious metals according to any one of claims 1 to 5, wherein 1 kg or less of the sulfide is charged into the melting furnace with respect to 1 kg of the recycled raw material. 7. The method for recovering precious metals according to any one of claims 1 to 6, wherein the recycled raw material is scrap of electronic and electrical equipment parts. The method for recovering precious metals according to any one of claims 1 to 7, wherein the recycled raw material includes substrate waste.

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