WO2011032696A1 - Method for recycling aluminium from drink cans - Google Patents

Abstract

The invention relates to a method for recycling aluminium from drink cans, in which the drink cans are comminuted to small particles in a shredder (6) and the particles are first cleaned of adhering drink residues and subsequently cleaned of adhering paint residues. The first cleaning stage is a spinning stage in a centrifuge (9). The second downstream cleaning stage is a thermal burning-off stage in a furnace (13). Finally, the thermally cleaned particles are melted in a melt vessel (15).

Description

 Method for reclaiming aluminum from beverage cans

description

The invention relates to a method for recycling aluminum from beverage cans with the steps of crushing the cans into small particles, cleaning the particles and subsequent further processing.

Beverages, such as beer, soft drinks, etc. are sold in aluminum cans to a considerable extent. These aluminum cans are recycled.

On the one hand, it is known to collect them and then to press them into bales. These bales are then placed in a known type of subsequent processing for recycling in a molten bath.

This method has the disadvantage that the bales of compressed cans relatively cool the molten bath into which they are placed, so that the aluminum contained in them does not melt immediately. Rather, the bale heats up slowly and especially the aluminum lying further inside the bale still forms thick oxide layers before melting. To remove these oxides from the molten aluminum bath, an appropriate amount of aggregates must be added, which brings with it the disadvantage of a high slag production. In addition, the formation of aluminum oxides deteriorates the yield of recycled aluminum.

In order to avoid this problem, it is described, for example, in WO 96/01332, to cut the pressed bales and thus to comminute the beverage cans contained in them into particles.

These can particles are then cleaned of adhering colors and finally pressed in the course of further processing into small pellets or nuggets. For cleaning it is proposed to give the crushed can particles with abrasive agents in a drum, so as to mechanically abrade adhering paint particles, etc. It is further proposed to subsequently expose such pre-treated can particles to a high temperature in order to incinerate adhering foreign particles.

Finally, the thus obtained purified can particles are pressed into pellets or nuggets.

A disadvantage of the method described is, in particular, that the introduction of foreign matter between the can particles for their abrasive cleaning these then only provided for cleaning foreign matter then again consuming to be removed. In addition, the abradingly cleaned surfaces of the can bodies, which are metallically bright, in turn tend to form oxide layers, in particular if they are then again exposed to a high temperature, which is basically beneficial for oxide formation. These oxides have the disadvantages described above. Object of the present invention is therefore to further develop such a known recycling process to the effect that it is easier and thus cheaper and also more effective in particular feasible.

This object is achieved in that a two-stage cleaning of the crushed Aluminiumdosenteilchen takes place with a first spin stage for centrifuging adhering moisture and with a downstream thermal Abbrennstufe.

By the spin stage for spinning off adhering liquid is prevented for the downstream thermal Abbrennstufe that undesirably still organic substances adhere to the can particles and are introduced with these in a Abbrennofen. These organic substances are residues of the beverages, such as beer or soft drinks, contained in the beverage cans. These substances can cause strongly adhering compounds to the can particles in the heat of the baking oven. Since according to the invention a mechanically abrasive cleaning of the can particles is dispensed with, no metallically bright surfaces are produced, so that no strong formation of oxides occurs.

In a particularly preferred embodiment of the invention, a solvent is added to the particles prior to the spin stage in order to be able to more easily dissolve adhering organic elements. Preferably, this solvent is water (H ₂ 0), which has a very good dissolution effect for the sugar and similar substances usually contained in soft drinks and beer etc.

In the subsequent cleaning in the spin stage, the solvent / water introduced into the aluminum particles can be spun off again well.

There is the possibility that due to this solvent, the particles moved past each other by the resulting friction also heat slightly, so that on the one hand, the solvent / cleaning effect is increased. On the other hand, the can bodies then already get slightly preheated in the subsequent burning stage. By this preheating the burn-off can be performed energetically cheaper. Furthermore, it is proposed that the subsequent processing step of the thermal firing step comprises the direct introduction of the cleaned can particles into a molten bath.

This has the advantage that the particles already heated in the burn-off stage reach the molten bath at a relatively high temperature. This is very favorable from an energetic point of view, since an already preheating of the can particles to a relatively high temperature can be used and the energy required for this need not be removed from the molten bath. As a result, a perceived as disadvantageous cooling of the molten bath is prevented. It is particularly preferred to precede the thermal burn-off stage with a storage bunker as a buffer store. This makes it possible, regardless of throughput fluctuations in the upstream system parts to operate the Abbrennstufe continuously and in particular dosed from this taking place delivery of can particles in the downstream melt and continuously.

It is proposed in particular to carry out the introduction of the can particles from the Abbrennstufe in the molten bath with stirring. By this stirring, the particles are not only added to the molten bath but deeply introduced into this and surrounded there from all sides by liquid melt. This leads to a rapid melting of the individual particles. Due to such a rapid reflow, the formation of oxides is prevented and overall the yield of recycled aluminum is significantly increased.

Further advantages and features of the invention will become apparent from the following description of a plant provided for the method according to the invention. It shows

Figure 1 is a schematic diagram of a system for carrying out the method according to the invention. FIG. 1 shows a feeding station 1, at which aluminum beverage cans to be recycled are entered into the plant.

About a hinge belt conveyor 2, the abandoned aluminum cans are transported to a Vibrorinne 3 and discharged from above on this.

In this case, an overband magnet 4 is arranged above this vibrating channel 3, with which ferromagnetic impurities are collected from the aluminum scrap. From the vibrating chute 3, the aluminum cans are distributed via distributing conveyor 5 to a plurality of shredders 6, in which the cans are shredded by cutting, chopping or the like into small aluminum particles. The can particles output by the shredders 6 are then transported via a scraping conveyor 7 to a metering device 8.

In this metering device, the comminuted can particles, a solvent such as water are supplied. Remains of beer, soft drinks, etc. sticking to the can particles are dissolved with this solvent.

The particles are then discharged from the metering device 8 into a centrifuge 9. In this centrifuge adhering liquid residues are thrown off. The solvent is thereby removed again. As a result, a first cleaning step for the can particles is realized. Due to the friction of the can bodies together also creates a certain frictional heat, which improves the cleaning of the can particles together with the friction.

About another scraper conveyor 10, the thus pre-cleaned can particles are once again passed through neodymium magnetic drums 1 1, where the can bodies are once again freed from ferromagnetic elements. Subsequently, the thus cleaned particles are introduced into a storage bunker 12.

This storage bunker 12 acts as a buffer for the subsequent kiln 13, in which color particles adhering to the aluminum doses are thermally dissolved and burnt. The Abbrennofen 13 is designed as a thermal cleaning drum and the resulting exhaust gases are cleaned in a filter 14 and possibly burned after. The resulting energy can also be used, for example, to heat the thermal cleaning drum of the Abbrennofens 13. The thus cleaned can particles are finally introduced into a melting furnace 15. This introduction takes place continuously and with constant stirring of the liquid melt bath. This constant stirring ensures that the individual can particles do not float on the melt but are stirred directly into the liquid melt bath and are completely surrounded by liquid melt there. As a result, a rapid melting of the aluminum particles is achieved, whereby the unwanted formation of oxide layers is prevented on the aluminum and results in a very high overall aluminum yield in the recycling process.

Claims

Claims 1. Process for recycling aluminum from beverage cans with the steps

 - Shredding the cans into small particles

 Purification of the particles and

 - a subsequent further processing,

characterized,

that the purification of the particles takes place in two stages,

 - first with a spin stage and

 - With a downstream thermal Abbrennstufe.

2. Method according to claim 1,

characterized,

the subsequent further processing comprises introducing the cleaned particles into a molten bath.

3. Method according to claim 1,

characterized,

that a solvent is added to the particles before the spin stage.

4. The method according to claim 3,

characterized,

that the solvent is water (H ₂ 0).

5. The method according to claim 2,

characterized,

that the thermal combustion stage is preceded by a storage bunker as a buffer memory.

6. The method according to claim 2,

characterized,

that coming from the combustion stage particles directly into a liquid

Melt bath are stirred.