DE4040377C1 - - Google Patents

Description

The previously practiced or tested waste disposal methods are inadequate and unconvincing the resulting environmental problems. That applies both for the intermediate storage as well as for the transport of and to the disposal facilities and especially for the processing of the waste, be it more common Household or industrial waste, special waste or already deposited landfill.

The classic form of disposal of house and industry All types of waste are still dumping today in and to large-scale landfill sites, sometimes very long transport routes. Associated environmental problems are well known, so far they have remained unsolved.

A known alternative solution for landfill dumping are Waste incineration plants. Burning waste brings  however, there are many other disadvantages. The combustion So far, this has been done with very poor efficiency in case of high pollution. High investment and Be drive costs are for the relevant incinerator gene required. Waste incinerators also have only for metropolitan areas as economically at least proven reasonable.

With the also known degassing of organic Waste was hoped to have a way gene, the waste incineration at least for a part of the to avoid waste disposal and economy to be able to operate appropriate small systems.

Irrespective of this, different pyrolysis processes were developed and tested, especially with regard to the Differentiate degassing methods. Upstream or downstream aggregates, such as sorting and shredding systems, Post-combustion chambers, dust filtering and exhaust gas cleaning are largely among themselves in waste pyrolysis comparable.

The known pyrolysis processes use three types of furnaces, namely:
1. shaft furnaces into which the pyrolysis material is introduced from above and which runs through the furnace shaft in the vertical direction,
2. Rotary tube furnaces in which the pourable pyrolysis material is mixed by rotation of the tube shaft and is brought into contact again and again with the heated tube walls, and
3. Fluidized bed furnaces, in which a sand bed that is in constant turbulence ensures heat transfer with the pyrolysis material.

Degassing reactors, such as from the AT-PS'sen 1 15 725 and 3 63 577 known, a variety of problems not yet satisfactorily resolved. There must for example, to improve the heat transfer pyrolyzing wastes are pre-shredded, which is high Costs. It is also necessary that with the organic substances for pyrolyzing atmospheric air in large throughputs, possibly with oxygen, must be introduced. The pyrolysis reactor works this way with little efficiency. Heating the waste runs relatively slowly and with considerable heat loss most. The well-known pyrolysis ovens must be economically Chen reasons have a relatively large volume and be can be found in the prevailing temperatures of over 450 ° C at the limit of mechanical strength, see above that they are only for operation at about atmospheric pressure are suitable. Finally, from the degassing reactors absolute gas tightness are required to the leak of pollutants to prevent what costly temperature loaded lock constructions and seals required Lich.

Known methods and their associated facilities due to the problems that have not yet been solved me not enforced in practice. About 80% of those so far operated systems have since been shut down.

So far, further processing has been particularly problematic processing of the essentially dusty pyro lysekokses, since its gasification does not exist because of its which flow characteristics are not or only after ver technically complex briquetting of the coal dust is possible.  

The storage and transport of waste products type of interest here occurs at relatively ge Ringer bulk density, whereby its physical and chemical instability as well as with biodegradable Garbage the odor and gas development particularly disadvantageous impact. To make matters worse, many waste disposal ter contain contaminated liquids that they at least in part during transportation or storage to lose. Precipitation washouts are included improper storage can hardly be avoided. The minor Bulk density of the disposal material leads to large storage and transport volumes. Is an interim storage of the Ent striving for good - for example because the Ent care for recycling and / or thermal recovery should be prepared - so are by state ver regulations wash-out bunkers considerable construction volume mens or specially equipped underground warehouse mandatory with the resulting high additional investment costs. Even the transport should Not least due to the low bulk density considerable costs.

In the case of chemically unstable disposal goods, in addition to strong ones Odor formation, gas formation or the like occur, so that particular for storage bunkers without additional gas disposal Ex there is a risk of explosion. Permanent ventilation, multiple Air changes per hour as well as additional filter and Si Security systems also form cost factors for the interim storage of the waste.

It is known for the transport of some disposal goods, with presses integrated into the vehicle, for example Transporting household waste easily pre-compressed. A subsequent thermal recycling of the waste is due to its low bulk density and the resulting resulting large volumes technically difficult.  

When using a tubular according to the invention Pyrolysis chamber, into which the material to be disposed is kept tion of a compressed state is introduced, he gives a very good thermal conductivity for and in that compacted waste due to the given air pores free pressure contact with the wall of the chamber. As has the advantageous length / diameter ratio Use of tube chambers, their length to the diameter is greater than 10 l. This geometry of the However, the pyrolysis chamber places a limitation on the capacity of such systems. For example used for high throughput volumes in diameter, which are significantly larger than 400 mm, result in from plants of inappropriately large height; Diameter for technically problem-free heights in turn limit the Throughput capacity of the disposal to be pyrolyzed good. It also results in relatively longer use Pyrolysis tubes significantly increased push-through forces. By the resulting mechanical loads are limited the practical pyrolysis temperature to values that are not should be above 500 ° C to prevent deformation of the pyrolysis to avoid pipe.

The present invention has for its object Industrial and household waste as well as all kinds of waste not only improved interim storage and transport conditions to create solutions, but in particular also an ener table and material use with improved us redesign degree of efficiency.

The task is inventively characterized in nenden part of claim 1 specified features. Advantageous further developments and refinements of these Task solutions result from the subclaims.  

The fact that the waste to be disposed of is initially under retention its mixed and composite structure, i.e. without the application use of costly sorting processes and systems Pre-compacted packages of approximately the same geometry the waste can be disposed of without difficulty an advantageously approximately tubular container one with a stuffing device, what un complicated and prone to failure. The occurrence pacting into a geometric shape, for example is adapted to a tubular container, prevents in the subsequent container-filling re-compacting other components of the disposal material hinder the process. In the compacted state that shows Disposal goods only about 1/3 to about 1/20 of his ur volume on what a correspondingly reduced t storage and transport volume, regardless of a downstream thermal degassing or pyrolysis of the material to be disposed of.

Basically, the first step of compaction the material to be disposed of using open packaging, such as Net wrapping or strap packaging, take place, its Introduction into a container that is only open at the end However, the advantage that it is also in tight confinement located so that the odor is reduced to a minimum is adorned and washings, for example by Nieder blows are not to be feared. For this you can without noticeable cost also the front of the container nisse be temporarily closed. For the given ones if applicable to transport and / or temporary storage closing thermal and material recycling of the sun compacted and sealed packaged waste there are a whole series of advantages. Let it be there are, for example, tubular, tightly filled containers in a chamber or continuous furnace  solution. The dwell time in such pyrolysis Chambers is based on criteria of the economic viability of the Ver driving optimizable. Restricting lengths / diameter conditions for tubular containers, which in turn pass through the degassing oven do not exist. There too Larger diameter containers can be used this way even bigger and bulky industry Dispose of goods wrecks equally.

Advantageous conditions for the thermal utilization of the Disposal goods consist in that all degassing pro products directly and without intermediate cooling of a high temperature can be subjected to turbo treatment. The emerging compressed coke, the remaining carbon, leaves easily bring out of such containers and the Apply high temperature treatment to at least partially to be gassed. A splitting arises Part of the carried water vapor fission gas (CO, H2). The products created by degassing are never used split the dimensional components. The reaction tem temperature is obtained by exothermic reaction of the resulting maintain dense coke with oxygen. That so freely The carbon dioxide that is set after the Boudouardian Balance with carbon to carbon monoxide. in the High temperature reactor will be an optimal implementation and Use of all products ensured.

The ver with the carbon gasification and fission gas formation Bound high temperatures lead to a direct benefit baren high-energy process gas without condensable organic components with greatly reduced water incurred in part. By the formed during the pressure pyrolysis dense coke and the process-related low flow speeds become dust particles in the Pro zeßgas reduced to a minimum.  

The meltable metallic and mineral inventory parts of the reaction products form at high temperature treatment in a melter gasifier a metal or Slag melt with very different parts Density, so that fabric components simply ge separates and can be used efficiently can.

The carbon gasification and fission gas formation, coupled with melting usable materials, can be advantageously in a shaft furnace itself perform known design, the dense Pro Zeßkoks containing shaft in a known manner oxygen is fed. This can be done in the solid pyrolysis residues temperatures of more than 1500 ° C without any problems produce in which both steels and other metals than also melt glasses. The application of these valuable materials can be done in fractional tapping or in overflow. The use of oxygen instead of air is from erhebli chem advantage to ensure high temperatures, lower Gas velocities and volumes as well as avoidance the formation of nitrogen-oxygen compounds.

The escape of those formed by thermal fission volatile compounds in the tightly filled container Sen is favored if the front is open and perforated Metal pipes or the like can be used. With appropriate Dimensioning arise with regard to the gas outlet, the manufacturing costs and the applicable degassing temperature ideal conditions.

The waste can be used for transport and intermediate Storage also in thermally usable, from chemically fe stem material pre-assembled existing containers introduced and later in the thermally stable degassing  tubes that are subjected to pyrolysis will.

When using the method according to the invention, it is advantageous, the unsorted waste in over 100 ° C preheated containers to a reduction in the subsequent degassing time ensure and by preheating the waste evaporate as much moisture as possible.

According to the invention, a lot is in a continuous furnace Number of containers, advantageous with tubular cartridges additional radial increasing their outer surface wrestle, circulated. In this way, the Maximize plant capacity. Become the containers for filling compaction before heat treatment and for Leave emptying in the oven after the heat treatment, see above their heat losses are reduced and the that of the overall system is minimized.

The compaction of household waste or the like can decisively ver be improved if that during precompacting Disposal material with a sterilizing hot gas, before preferably superheated steam is applied. This will increase the possibility of its plastication and the chemi cal stability of the waste and the storage resistance without odor and gas formation.

Because of the desired high thermal conductivity to and within the material to be disposed of in the container, but also for reasons of storage, transport and optimal disposal volume for degassing, it is advisable to fill the container in such a way that the filling density for household waste is approximately 1 kg / dm ³ . A periodically operating hammer can be used as a stuffing device for the densifying filling of the tubular containers, the hammer being driven mechanically, hydraulically or pneumatically.

If the densely filled pipes for a long time between stored before being subjected to thermal recovery leads, it is advantageous if the end faces of the pipe filled with post-compressed waste shaped container with thermally decomposable films or Coatings are covered. In this way a direct emission of pollutants to the environment is excluded on the other hand, odor nuisance is also avoided the. The thermally decomposable cover can then be used directly can be used thermally in pyrolysis. In addition to art Fabric films are suitable for this, for example, bituminous Paintings that are inexpensive and easy to apply that can. Otherwise the pipes behave at users practicing the pyrolysis process of the invention self-cleaning. Their use not only optimizes that Conditions for pyrolysis itself, but reduced at their use as a transport container the transport volu around 80%. The result of pyrolysis inside the compressed pyro produced in the tubular containers lysekoks has excellent flow properties ten so that it be for subsequent coal gasification is particularly suitable.

The method described above is the first time at least part of the natural moisture of the garbage the described hydrocarbon gas reaction to combustible gas converted.

Claims (8)

1. Process for interim storage, transportation and / or energy and material recycling of industrial, special and domestic waste as well as industrial wrecks of different composition and the like Ent care goods of all kinds, characterized in that the waste material while maintaining its mixed and composite structure to a multiple compressed to its original bulk density and subjected to pyrolysis in compressed form, that the entirety of the pyrolysis products under elevated pressure is subjected directly to high-temperature exposure without intermediate cooling, in which the compressed carbon fractions of the pyrolysis products gasify and at least a part of the water vapor carried along is split and the gaseous constituents from the totality of the pyrolysis products are split into low-molecular components and likewise gasified, and finally the metallic and mineral constituents are removed the remaining total are melted out and separated. 2. The method according to claim 1, characterized in that the High temperature exposure with the addition of oxygen like this takes place that the carbon dioxide from the exothermic reaction of carbon with oxygen according to Boudouard's Reaction is converted into carbon monoxide and that Temperatures of more than 1500 ° C on the whole of the reaction products act. 3. The method according to claim 1 and claim 2, characterized records that the material to be disposed of is initially too geometric to a Package shape adapted packages approximately the same  Geometry is compacted so that the compacted Ent goods with the help of a darning device in the derar term containers is compressed and that the Ent care afterwards in this compacted state remaining in the container is subjected to pyrolysis. 4. The method according to claim 1, characterized in that as Containers used open metal tubes on the front will. 5. The method according to claim 1, characterized in that the material to be disposed of in tubular containers with a Temperature greater than 100 ° C is compressed where at the steam arising from the moisture of the disposal good through gas outlet channels of the container leads. 6. The method according to claim 1 to 5, characterized in that that the heat treatment of the in the compressed state in Container of waste to be disposed of in one go barrel furnace takes place in a variety of containers is in circulation. 7. Method according to at least one of the preceding An sayings, characterized in that the waste at least during compaction with a sterile flowing hot gas. 8. Procedure according to at least one of the preceding An sayings, characterized in that the end faces of the tubular filled with compacted waste Containers with thermally decomposable foils or Be layers are sealed.