DE102009041789A1 - Process for recycling aluminum from beverage cans - Google Patents

Abstract

The invention relates to a method for recycling aluminum from printed beverage cans, in which the beverage cans are comminuted into small particles and these are first cleaned of adhering beverage residues and then adhering paint residues. The first cleaning stage is a spin stage. The second downstream cleaning stage for the paint is a thermal cleaning stage to which an exhaust gas afterburning is assigned. The thermally cleaned particles are then stirred into a molten bath and melted.

Description

The invention relates to a method for recycling aluminum from printed 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 to a considerable extent in aluminum cans, which are known to be a u. a. the content of the imprint. These aluminum cans are recycled.

For this purpose, it is known on the one hand to collect them and then press 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.

Also located on the cans imprints or derived from these color leads in the described method to large amounts of unusable slag and thus significantly deteriorates the yield of recycled aluminum.

To avoid these problems, for example, in the WO 96/01332 described to cut the pressed bales and thus reduce the beverage cans contained in them into particles. These can particles are then cleaned of adhering colors derived from the print and finally pressed into small pellets or nuggets during further processing.

For the cleaning of the printing inks is proposed to give the crushed can particles with abrasive agents in a drum, so as to mechanically abrade adhering paint particles. It is further proposed to suspend such pre-treated can particles then a high temperature to burn adhering foreign and color 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 abrasive agents that are introduced between the can particles for their cleaning of adhering paint residues, after cleaning again consuming between the crushed can particles must be removed because these funds are provided only for cleaning. In addition, the abrasive cleaned surfaces of the can bodies, which are metallic bright, again tend to form oxide layers, especially when they are then exposed again 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 cleaning stage for adhering to the particles color.

By the spin stage for spinning off adhering liquid is prevented for the downstream thermal cleaning stage on the one hand, that in the thermal cleaning stage energy must be applied to energy-consuming evaporation of adhering liquids. In addition, it is prevented that unwanted organic substances still adhere to the can particles and are introduced with these in an intended for the purification stage furnace. These organic substances are residues of the beverages, such as beer or soft drinks, contained in the beverage cans. These substances may undesirably cause compounds reactive with the can particles in the heat of the flash furnace.

In the subsequent thermal cleaning stage, the ink residues still adhering to the can particles are cleaned by thermal means, ie in particular burned or de-inked. For this process temperatures between about 300 ° C and 500 ° C, preferably about 400 ° C have been found to be particularly suitable.

The resulting in the burning or devolatilization of paint residues gases are derived from the thermal cleaning stage and a Exhaust post-combustion supplied. This prevents pollutants from being released into the environment.

If necessary, it is possible to downstream of the exhaust after-combustion as a further element filter to meet even the highest environmental requirements.

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 O), which has a very good dissolving action for the sugar and similar substances usually contained in soft drinks and beer, etc., and thus dissolves the sugar well for further treatment.

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

Furthermore, it is proposed that the subsequent step of the further processing of the thermal cleaning 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 thermal cleaning 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 between about 300 ° C. and 500 ° C., preferably about 400 ° C., can be used and the energy required for this is not taken from the molten bath must become. As a result, a disadvantageous cooling of the molten bath is prevented, which can thus be more easily maintained at temperatures of about 720 ° C to 730 ° C, preferably by about 750 ° C to 760 ° C.

It is particularly preferred to precede the thermal cleaning stage a storage bunker as a buffer memory. This makes it possible, regardless of throughput fluctuations in upstream equipment parts to operate the thermal cleaning stage continuously and in particular dosed from this taking place delivery of can particles into the downstream melt and continuously made.

In this case, it is proposed, in particular, to carry out the introduction of the can particles from the thermal cleaning stage into the liquid molten bath, thereby producing a collection vortex ("vortex"). Through this collection strudel, the particles are not only abandoned on the molten bath but deep into it and surrounded there in no time from all sides of liquid melt. This leads to a rapid melting of the individual particles. Due to such rapid melting, in particular it is also prevented that individual particles burn off on the surface of the molten bath. Thus, the total yield of recycled aluminum is to increase significantly.

Further advantages and features of the invention will become apparent from the following description of an apparatus provided for the inventive method. It shows

1 a schematic diagram of a system for carrying out the method according to the invention.

In the 1 you can recognize a feeding station 1 on which aluminum drink cans to be recycled are entered into the system. These aluminum cans are provided with imprints, the imprints or the color required for this makes recycling difficult.

Via a hinge belt conveyor 2 the abandoned aluminum cans become a vibratory chute 3 transported and delivered from above on this.

About this vibratory chimney 3 is an overband magnet 4 arranged, are collected with the ferromagnetic impurities from the aluminum scrap.

From the vibratory gutter 3 The aluminum cans are over distribution conveyor 5 on several shredders 6 in which the cans are shredded by cutting, chopping or the like to small aluminum particles.

The of the crushers 6 dispensed can particles are then a Kratzförderer 7 to a metering device 8th transported.

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

The particles are then removed from the dosing device 8th in a centrifuge 9 issued. In this centrifuge adhering liquid residues are thrown off. Also the solvent and the solution of this dissolved on the can particles adhering residues are thereby removed again. As a result, a first cleaning step for the can particles is realized.

About another scraper conveyor 10 The thus pre-cleaned can particles are again on Neodymmagnettrommeln 11 where the can bodies are once again freed from ferromagnetic elements.

Subsequently, the thus cleaned particles in a storage bunker 12 entered.

This storage bunker 12 acts as a buffer for the subsequent oven 13 in which a thermal cleaning of the can particles takes place and the paint particles adhering to the aluminum can particles are thermally dissolved and burnt or burned. The oven 13 is designed as a thermal cleaning drum and the resulting exhaust gases are post-combusted and possibly in a filter 14 cleaned. The energy produced during the afterburning can also be used, for example, for the thermal cleaning drum of the furnace 13 to heat. Inside the oven 13 the shredded can particles and the hot gases that clean them are conducted in countercurrent to each other, which is very effective in terms of energy.

The can bodies which have been cleaned in the thermal cleaning stage are finally put into a melting furnace 15 brought in. This introduction takes place continuously and with constant stirring of the liquid melt bath.

Through this constant stirring, the formation of a vortex is achieved in the molten bath, so that the individual can particles do not float on the melt but are sucked directly into the liquid molten bath directly in the area of the vortex where they are immediately completely surrounded by liquid melt. As a result, a rapid melting of the aluminum particles is achieved without individual aluminum particles burning on the melt floating. This prevents the undesirable formation of slag and results in an overall very high aluminum yield in the recycling process.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 96/01332 [0006]

Claims (8)

Process for recycling aluminum from beverage cans printed with color, comprising the steps of - crushing the cans into small particles - cleaning of the particles and - a subsequent further processing, characterized in that the cleaning of the particles takes place in two stages, - first with a spin stage and - with a subsequent thermal cleaning step for the color adhering to the particles. A method according to claim 1, characterized in that in the thermal purification stage gases are supplied to a Abgasnachverbrennung. A method according to claim 1, characterized in that the Abgasnachverbrennung a filter is connected downstream. A method according to claim 1, characterized in that the subsequent further processing comprises introducing the cleaned particles into a molten bath. A method according to claim 1, characterized in that a solvent is added to the particles before the spin stage. A method according to claim 5, characterized in that the solvent is water (H ₂ O). A method according to claim 1, characterized in that the thermal cleaning stage is preceded by a storage bunker as a buffer memory. A method according to claim 1, characterized in that the particles coming from the thermal cleaning stage are introduced directly into a liquid molten bath stirred to form a vortex.

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