DEJ0000788MA - Use of flotation treatment for the recovery of metals from industrial waste products - Google Patents

Description

As is well known, the processing of ores of various kinds through flotation has received completely new technical possibilities in the last few decades. With the use of swimming pool processing, ore deposits are still processed profitably today, which due to their low content previously had no economic uses.

The purpose of the application is to apply this tried and tested flotation option to a previously unknown area, namely flotation also for the recovery of metal residues. As is well known, the latter are for the most part processed again by metal works in order to return the valuable metals they contain to the national economy.

The metallurgical process has certain disadvantages when using industrial waste products. An example of this is that copper smelters ultimately see their main task in collecting the copper contained in the residues as little as possible without large losses of this metal. In practice, however, the fact is stored in such a way that relatively few residues, which only contain the copper-containing metal, get into the copper smelters. The vast majority of all metal residues, on the other hand, is known to consist of metal alloys. In addition to copper, gunmetal, for example, may contain valuable tin of up to 14%. In order to stick to this example, it must be pointed out that this very valuable tin content is largely lost in the smelting of copper. Incidentally, the loss of slagging in a hut today, if it works well, is at least 1%. It should also be noted that this smelting process is also very expensive.

Attempts have therefore been made several times to avoid the disadvantages of smelting industrial products. One way out is partially wet mechanical processing, which exploits the difference in specific opposites through digestion and sludge. But this process also has disadvantages, if, for example, it is necessary to collect the residues, then processing cannot achieve this goal without the help of the Hüttenweg.

In addition, this wet mechanical preparation has the disadvantage that the digestion inevitably results in unpleasant grinding losses, which can in part be compensated for by good stove work. However, oxides are lost in this process.

The purpose of the present invention is to provide new possibilities in the field of metal residue recovery.

It is not yet known that flotation (swimming pool treatment) is also used for the recovery of metals from waste from the processing industry. This new way should be briefly described:

Since it is well known that flotation can only be used technically if the digestion is uniform, especially fine, about 0.30 mm in grain size, it is not possible to do without a corresponding pre-comminution in the intended sense. There are also many metals that are tough due to their alloy and therefore cannot be finely ground to a greater or lesser degree to the necessary grinding fineness that is required for flotation. Copper and its alloys, for example, have this tough peculiarity. Therefore, when using flotation for such waste products, the tried and tested wet mechanical treatment cannot be completely dispensed with. The lumpy metal as well as the granules are therefore expediently separated in certain grain sizes by setting and stove work before flotation. After the wet mechanical treatment, the pulp passes through a ball mill with a return device in order to ensure the required grinding fineness for the subsequent flotation. The pulp then continuously passes through the flotation system, which is harmoniously coordinated with the upstream wet mechanical treatment in terms of throughput capacity.

While the finest metal sludge as well as the oxides were carried away with the mountains to the dump in the past during the wet mechanical processing and thus unavoidable damage occurred, the flotation now captures this sludge. With the xanthates to be used on a case-by-case basis, these inevitable losses can now be obtained down to a fraction of one percent due to the known technical possibilities.

This application of flotation technology opens up new economic opportunities. As you know, process

Copper smelters, which are only cited as an example in this context, do not have such copper residues below a copper content of 10%. This does not mean that the smelter is technically not able to process such poorer residues in practice, but the profitable economic viability is no longer given with contents lower than 10% copper. In the processing industry, however, there are considerable large quantities that do not have this copper content. Such poorer materials go, if they are not captured by a wet mechanical treatment, which, however, may not fall below a lower limit for copper for economic reasons, and the metal contained is thus buried for all time.

If, on the other hand, deposits with only 2% copper can be processed profitably in ore processing today using flotation, more or less the same applies to the collection of industrial waste products. The present invention is therefore of great importance from an economic point of view. The recovery possibility on this drawn new basis is not limited to the recapture of waste products from the heavy metals industry, but the current high level of flotation technology enables more or less recovery of the metals in waste products from all types of industry. Another example is the recovery options in the stainless steel industry, where previously valuable alloy metals such as cobalt, tungsten, molybdenum and nickel can be returned to the economic process.

Claims (1)

Use of flotation (swimming pool processing) for the recovery of metals from metal residues, such as those inevitably generated during processing in foundries, rolling mills, lathes, grinding shops, as well as during surface refinement in electroplating plants, as well as during tinning, lead-coating and galvanizing.