WO2001053547A1 - Method for separating a fraction containing ne metals into the respective ne metals by means of surface colouring - Google Patents

Abstract

The invention relates to a method for separating a fraction containing NE metals into the respective NE metals. Said fraction containing NE metals is treated with at least one solution of one or more inorganic and/or organic reagents so as to specifically surface-colour the individual NE metal part according to the respective NE metal. The individual NE metal parts of the fraction are then sorted according to the respective surface colouring, especially picked automatically.

Description

METHOD FOR SEPARATING A FRACTION CONTAINING NE-METALS INTO THE RESPECTIVE NE-METALS BY MEANS OF SURFACE COLORING

Technical field

The present invention relates to a method for separating a fraction containing non-ferrous metals into the respective non-ferrous metals, wherein the fraction containing non-ferrous metals is treated with at least one solution of one or more inorganic and / or organic reagents, as a result of which a specific surface coloration of the individual non-ferrous metal fraction components depending on the respective non-ferrous metal is effected, and then the individual non-ferrous metal fraction components are sorted according to the respective specific surface color, in particular automatically credited.

State of the art

As part of the recycling of scrap and / or metal-containing waste, non-ferrous metal mixed products (NE = non-ferrous) are obtained, but their further sorting is currently only possible to a limited extent.

The separation of magnesium or aluminum by floating-sink sorting is known in the prior art. However, the magnesium or aluminum concentrates available here still contain non-metals, such as rubber. Ceramics. Gla ^. Plastics, eic. which can be separated by using eddy current sorting, but is technically and economically complex. For the further sorting of such non-ferrous metal mixed products or heavy metal products, there are currently no satisfactory solutions or at most only partial solutions. Attempts have been made, among other things, to separate the heavy metals or non-ferrous metals by selective melting, by means of ferrofluids (MHS sorting), by aerostream sorting (screening) of narrow grain size classes and by the combination of sieve classification, current classification and eddy current sorting.

However, either the separation results achieved in the abovementioned process variants were inadequate (in particular as a result of the very different bar shapes of the non-ferrous metals) or they ultimately failed for economic reasons.

Since it has been evident for some time that the mass flow sorting processes are not expected to result in new approaches for sorting non-ferrous metal mixed products or heavy metal products, attempts have recently been made to sort individual items (automatic certification) for to introduce the above problem. Despite extensive efforts, however, no satisfactory results have so far been achieved.

Since the certification by means of X-ray fluorescence analysis and atomic emission spectral analysis requires a linear separation or arrangement of the pieces, which causes high operating costs, systems based on such a detection principle have not become established. With the use of CCD color cameras, a flat separation and thus a higher throughput (up to 10 t / h ° m working width) as well as the sorting of small pieces of non-ferrous metal scrap (up to approx. 5 mm) is possible, however, such a detection method is possible such metal separations or. -Sorts limited, in which there are sufficient color differences between the metals to be separated. Presentation of the invention

The present invention is therefore based on the object of providing a process for separating a fraction containing non-ferrous metals into the respective non-ferrous metals, which on the one hand is said to be economically superior to the separation processes known in the prior art, but on the other hand also a satisfactory separation to ensure non-ferrous metals with high throughput. In particular, such a method should enable individual item sorting.

These objects are achieved by the features characterized in claims 1 to 8. In particular, a method for separating a fraction containing non-ferrous metals into the respective non-ferrous metals is provided, which comprises the following steps after optionally crushing the fraction containing non-ferrous metals and separating the ferromagnetic components from the fraction:

a) treating the non-ferrous metal fraction obtained with at least one solution of one or more inorganic and / or organic reagents to produce a specific surface color of the individual non-ferrous metal fraction components depending on the respective non-ferrous metal and

b) Sorting the respective non-ferrous metal fraction components according to the respective specific surface color of the individual non-ferrous metal fraction components.

Best way to carry out the invention

By pretreatment of the above-obtained non-ferrous metal fraction in step a) of the process according to the invention with at least a solution of one or more inorganic and _'Oüer organic reagent is a specific surface staining of the different non-ferrous metal fraction components in dependence on the respective non-ferrous metal caused, which creates the conditions for the actual sorting of non-ferrous metals.

By means of the method according to the invention, individual recyclable material fractions of the respective non-ferrous metals can be produced or obtained with simple means and in an extremely cost-effective manner via a sorting of individual pieces.

In a preferred embodiment of the method according to the invention, the sorting process is carried out in step b) of the method according to the invention by means of an automatic klaubung. In a particularly preferred embodiment, the automatic picking is carried out using one or more CCD color cameras.

Depending on the type or composition of the fraction to be separated and containing non-ferrous metals, an optional comminution step precedes the process according to the invention. The fraction containing non-ferrous metals can be comminuted, for example, in a hammer mill or the like. The prior separation of the ferromagnetic components of the method according to the invention is preferably carried out by magnetic separation. The optionally crushed starting fraction can be fed to a magnetic separator, for example.

In step a) of the method according to the invention, the non-ferrous metal fraction is treated with a solution of inorganic and / or organic reagents to produce a specific surface color of the individual non-ferrous metal fraction components depending on the respective non-ferrous metal. For example, the solution in step a) is an aqueous copper nitrate solution whose concentration is in the range from 1 to 5% by weight. based on the total weight of the solution. The treatment time or contact time in step a) can be, for example, 1 to 30 minutes.

If, for example, a 1% by weight aqueous copper nitrate solution is used in step a), the zinc and zinc reading rings contained in the non-ferrous metal fraction show a black upper surface coloring, aluminum and aluminum alloy surfaces an unchanged surface and magnesium and magnesium alloys a bluish surface coloring.

Depending on the kinetics of the color reaction or coloring and the required contact time with the solutions used in step a), the chemical pretreatment in step a) to produce the respective specific surface color can be carried out in separate containers, when stored on flat surfaces or on conventional conveyors.

In order to achieve a largely uniform and possibly stronger or stronger surface color, it may be advisable to subject the non-ferrous metal fraction components to mechanical stress, e.g. in a comminution machine with relatively low stress, and / or to undergo a washing process.

In step b) of the method according to the invention, one or more of the non-ferrous metals from the group consisting of zinc, aluminum, copper, magnesium, lead and their alloys and non-magnetic alloyed steel are preferably sorted out. The automatic clawing of the metal pieces can preferably be carried out in the moist state.

The separation of the respective non-ferrous metals from the fraction containing non-ferrous metals in step b) was in particular also carried out step by step by successively generating a specific surface color for the respective non-ferrous metals to be sorted out.

Industrial applicability

The invention enables a fraction of a non-ferrous metal-containing fraction to be separated into the respective non-ferrous metals, taking into account a single piece sorting with high throughput.

Claims

claims 1. A method for separating a fraction containing non-ferrous metals into the respective non-ferrous metals, comprising the steps of optionally comminuting the fraction containing non-ferrous metals and separating the ferromagnetic components from the fraction, characterized by a) Treating the non-ferrous metal fraction obtained with at least one solution of one or more inorganic and / or organic reagents to produce a specific surface color of the individual non-ferrous metal fraction components depending on the respective non-ferrous metal and b) Sorting the respective non-ferrous metal fraction components according to the specific surface coloring of the individual non-ferrous metal fraction components. 2. The method according to claim 1, characterized in that the sorting in step b) is carried out by means of an automatic klaubung. 3. Verfaliren according to claim 2, characterized in that the automatic certification is carried out using one or more CCD color cameras. 4. The method according to any one of claims 1 to 3, characterized in that the separation of the ferromagnetic components is carried out by means of magnetic separation. 5. The method according to any one of claims 1 to 4, characterized in that the solution in step a) is an aqueous copper nitrate solution. 6. Verfaliren according to any one of claims 1 to 5, characterized in that the treatment time in step a) is 1 to 30 minutes. 7. The method according to any one of claims 1 to 6, characterized in that the non-ferrous metal fraction is subjected to a mechanical stress and / or a washing process before step a). 8. The method according to any one of claims 1 to 7, characterized in that in step b) one or more of the non-ferrous metals from the group consisting of zinc, aluminum, copper, magnesium, lead and their alloys and non-magnetic alloyed steel, sorted out will or will.