DE3932366A1 - Disposal of shredded material - involves removing ferrous material and sifting residual material by blowing air through it - Google Patents

Abstract

Waste material such as metal, wood, plastic etc. is disposed of by first shredding the material (1) and then removing any ferrous metal by magnetic means. The residual material is then sifted (2) by blowing air through it in order to separate the dust from the larger fragments. The air used for sifting may subsequently be used for cooling purposes such as cooling hot ashes. Alternatively the shredded material may be burnt and the resultant ash sifted by blowing air through it. In this case the air may be subsequently used for heating purposes or as combustion air for burning the shredded material. USE - Disposal of shredded waste material.

Description

The invention relates to a recycling process for shredded goods.

Various everyday objects made of different materials exist and are partly also filled with operating materials, are generally shredded for disposal, d. H. they will follow Removal of directly reusable assemblies and if necessary mechanically crushed after emptying the operating materials.

After crushing, material components, e.g. B. magneti FE metals, separated from the shredded material and the industrial len further processing forwarded.

Inhomogeneous residual materials from various and operating materials. In automobiles, these are e.g. B. non-magnetic metals, wood, various types of plastic, glass, textiles, Oils, fuels, other liquids, etc., the so-called Shredder residue are referred to.

Such shredder residues are to be disposed of as special waste, though Legislators generally prescribe reusable components of household goods to extract and into the cycle of the host to recapture assets.

Such shredder residues usually become very expensive disposed of in suitable landfills. Alternatively there are combustion plants for these residues in the planning, in which from the Heating value of the residues energy is recovered and used. A return of original, material components in the economic cycle does not take place. On the contrary, it will Ash is produced, which in turn is a waste that is subject to landfill represents.

As there are currently no techniques or industrially applicable are that allow recycling of the entire shredder residue,  are technically feasible and economically represented asked partial solutions, which the partial repatriation of individual, original fabric components in the cycle of economic goods allow.

The shredder residue shows for all solid components about the same spread in the sieve line, so that a selection by grain size seems illusory.

There are sub between the individual solid components differ in specific weights. Kick here however overlays on; e.g. B. Wood-plastics, aluminum Plastics, glass metals etc.

To avoid these disadvantages, the invention provides beat, wind sifting and / or flotation processes for bring the grain separation to use, if necessary under additional integrated use of the classifier wind and / or the classification liquid.

It should be borne in mind that the method of swimming classification, which mainly uses water as a separation medium is used, then raise problems if

• - Forced components wetted with water afterwards must be disposed of thermally (incinerated) (additional Energy requirement for water heating,
• - Forced components wetted with water afterwards should be and then higher because of the higher weight Cause landfill costs,
• - original, toxic liquids are present in the residue, that can mix with the water or dissolve in the water, and
• - heavy fines from the solid components heavy form sludge to be treated.

In the presence of toxic liquids in the back levels (e.g. gear oils, brake fluids etc. in the car mobile or CFC in cooling units such as ice cabinets etc.) the first post-disposal stage is always thermal Stand cleaning and only then is separation process at the Ash a recycling process can take place.

There is the possibility of a limited grain separation by Wind screening process for both original shredders residue as well as its ashes after a thermal Cleaning.

There are adjustable, controllable, single and multi-stage process steps applied to thereby referring to the weight of the selected components optimize separation.

After mechanical extraction of the intended components from The cleaned sifter wind can optionally be sifted into the recycled or as part of the combustion air thermal cleaning can be used. The latter is recommended if toxic fine dust and / or vapors or gases in can get the classifier wind. This type of sighting is shown in diagram I as an example.

When separating components by air separation of an ash, e.g. B. after thermal cleaning, one or more graded sifting is carried out according to the same pattern. Here he can Sifter wind as cooling medium for the hot ash (up to 1000 ° C) and / or in the circuit as a preheated ver combustion air can be used for thermal cleaning. This type of process is shown as an example in Diagram II.  

A swimming classification of the ash from shredder residues is shown in diagram III as an example as a single-stage system posed. Here the classification liquid, e.g. B. water, can be used to cool the ashes.

Legend for diagram I:

Two-stage combustion screening and classifier wind cycle

1 dosed feed of original shredder residue
2 1st sifter stage
3 regulated sifter wind supply
4 classifier downwind with intended light component
5 filters to separate the light components from the wind
6 intended lightweight components for recycling
7 cleaned downflow to circulation
8 deficit to second classifier
9 2nd sifter stage
10 regulated sifter wind supply
11 Classifier downwash with light component intended
12 filters to separate the middle component from the wind
13 separate funds for recycling
14 clean downflow to circulation
15 circulation fans
16 heavy components for thermal cleaning
17 thermal cleaning
18 Ash removal from thermal cleaning
19 Additional air supply when using the circulating wind as combustion air
20 controlled combustion air supply
21 Exhaust gas from thermal cleaning for exhaust aftertreatment
22 cleaned circular wind to classifier stages

Legend for diagram II:

Air sifting of hot ashes with integrated direct cooling and classifier wind cycle

1 dosed supply of hot ash
2 1st sifter stage
3 regulated sifter wind supply
4 Downwind with selected light components
5 additional cooling air supply
6 filters to separate the light components from the wind
7 separated light components for recycling / landfill
8 cleaned classifier wind to cycle
9 solid components for 2nd classifier
10 2nd classifier
11 regulated feed sifter wind
12 Downwind with a selected middle component
13 additional cooling air supply
14 filters to separate the middle component from the wind
15 Middle component for recycling / landfill
16 cleaned classifier wind to cycle
17 circuit blowers
18 Sifter wind preheated to combustion air
19 Solid component for recycling / landfill

Legend for diagram III:

Component separation through swimming classification with integrated Ash cooling

1 regulated supply of hot ash
2 immersion cooling pools
3 Deduction of the cooled heavy component for reuse / landfill
4 Deduction of the cooled light component for reuse / landfill
5 Fresh water supply
6 vapor evacuation
7 Vacuum suction and removal of non-condensable gases
8 spray condenser
9 Condensate outlet
10 water reserve
11 Water circuit for air cooling
12 Cooling air supply
13 Fresh water supply
14 Spray water drainage and injection
15 Sludge removal for recycling / landfill

Claims (7)

1. Process for the extraction of solid components from shredded material, characterized by

• - Application of techniques of wind classification and / or
• - the washing classification (flotation, swimming preparation) and / or
• - Combination of these process technologies with integrated ter reuse and / or use of the classifier wind or the classification liquid.

2. The method according to claim 1, characterized by

• - Use on ashes from shredder residues.

3. The method according to claim 1 and / or 2, characterized by

• - Application of the process of wind sifting and washing classification in combination.

4. The method according to claim 1, characterized in that

• - After sighting the classifier wind an incineration system is supplied as combustion air.

5. The method according to claim 1, characterized in that

• - The classifier wind as a cooling medium for hot bulk materials, e.g. B. ashes is used.

6. The method according to claim 1, characterized in that

• - The classifier wind is fed to a combustion process as preheated combustion air.

7. The method according to claim 1, characterized in that

• - The classification liquid as a cooling medium for hot bulk goods such. B. ash is used.