DE4011945C1 - Waste material pyrolysis system - compresses material and heats it by friction against chamber walls - Google Patents

Abstract

A pyrolysis process for degassing organic substances, eg household or industrial waste, includes using a pyrolysis chamber. The material to be treated is comprested and fed into the chamber, and is then fed through the chamber. The heat is added by friction with the chamber wells. The pyrolysis products formed are removed at increased pressure. Pyrolysis pref. takes place at between 250 and 500 deg.C. USE/ADVANTAGE - The hyrolysis process for organic waste is simple and efficient, and the vapour, gases etc formed, are all utilised.

Description

With increasing prosperity, industrial waste and household waste rise above average. The greater sensitivity of the population to environmental pro bleme also leads to questions of waste generation and disposal a much higher priority win. The previous proposed solutions for over Waste disposal is insufficient.

The classic form of disposal of house and industry Waste of all kinds is still landfill today without actually causing the disposal problem would be solved. Around 80% of all waste generated treated that way. The high environmental impact and lack However, landfill areas forced alternative solutions gene.

One saw a way out in waste incineration plants. The Waste incineration involves a variety of Disadvantages such as poor efficiency, high Pollution and high investment and operating costs. In addition there are waste incinerators due to the high cost only for metropolitan areas makes economic sense without removing the pollutant emission could be solved satisfactorily.

With the degassing of organic waste believed one to have a way to dispose of the garbage to avoid combustion and small systems economy to be able to operate.

In recent years, a large number of Pyrolysis process developed and tested. This ver driving differ mainly in terms of Ent gassing units, while the downstream units  gate, such as combustion and post-combustion chamber, Dust filtering and exhaust gas cleaning, largely at the current state of the art are comparable.

The degassing units known today can be divide into three types:

• 1. Shaft furnaces into which the pyrolysis material is from above is introduced, and the furnace shaft in verti calender direction traversed by gravity.
• 2. Rotary tube furnaces, where by rotating the tube shaft through the free-flowing pyrolysis material mixes and with the warmed walls again and again Is brought in contact, and
• 3. Fluidized bed furnaces, in which a ver whirling sand bed for one Heat transfer with the pyrolysis material ensures.

The degassing reactors described, such as known from AT-PS'en 1 16 725 and 3 63 577 are with a Numerous disadvantages and technically not yet satisfactorily solvable problems. All three Reactor type is common,

• 1. that to improve the heat transfer to pyrolyzing waste must, which causes high costs,
• 2. that with the organic substances for pyrolyzing Atmospheric air with oxygen are introduced must in the pyrolysis reactor to burns and Deflagration and pyrolysis  products diluted with combustion gases.
• 3. that the heating of the waste is relatively slow runs and ver with significant heat loss is bound because the efficiency is poor and the nitrogen introduced also heats up and with must be disposed of.
• 4. The degassing reactors described must be off a relatively large volume for economic reasons own and are at the prevailing temperatures of over 450 ° C at the limit of mechanical loading resilience, so that they are only for operation at et wa atmospheric pressure are suitable.
• 5. Furthermore, the degassing reactors produce gas tightness required to prevent leakage and prevent active substances. For this reason they have complex temperature loads Lock constructions and seals for one and spreading the pyrolysis material or the pyro lysis residues.

Shaft furnaces carry out low-temperature pyrolysis Bonding the pyrolysis material to form channels and bridges. Rotary yards are because of their mechanical movement Lock technology and the sanding inert stock share high signs of wear in the pyrolysis material exposed. All reactor ovens are so bad ten efficiency that one with rotating and fluidized bed has suggested the heat transfer through constantly recycled hot sand and / or heated steel or Improve ceramic balls.

In addition, there were difficulties in operating the pyrolysis units; in low-temperature pyrolysis by Ver  stick the pyrolysis residues due to their relative high content of wax or tar-like substances; in high temperature pyrolysis by melting and Crusts of slag.

All known methods are based on technical problems to be solved in the pyrolysis furnaces and / or the negative energy balance failed. Approx. 80% of all built systems have meanwhile been decommissioned. The hopes with the help of the known pyrolysis processes about an economical and environmentally friendly ther to have a mixed disposal concept not fulfilled.

The invention has for its object to provide a method for pyrolysis of organic substances of all kinds, in which the degassing unit - called pyrolysis chamber in the following - has a high degree of efficiency with great performance, works trouble-free and reliably and in which the pyrolysis products, such as Steam, gases and coke are used optimally in terms of energy. In addition, degassing units have to be created that work economically even in small systems and can be used to move them if necessary.

The task of the invention is characterized by the Part of claim 1 solved, the subclaims advantageous further developments.

By compressing the pyrolysis material, the pore volume becomes lumen reduces what the thermal conductivity is noticeable improved and the size of the pyrolysis chamber mini lubricated. The small radiation area of the pyrolysis chamber  also guarantees a relatively low heat loss.

A forced promotion of the compressed pyrolysis material ensures constant pressure contact between the Pyrolysis and the heated chamber walls, so that heat transfer from the chamber walls to the pyro lysegut is optimized.

In addition, the volume loss in the pyrolysis chamber by degassing (pyrolysis gas / water vapor) and / or discharge of solid components by refilling and post-compression with pyrolysis.

Because the pyrolysis material only has to be compressed contains little air volume, is its Wäremleitver may mean compared to the usual bulk density tends to improve the insulation effect of the air largely reduced.

The higher pressure in the pyrolysis chamber guarantees one better forced flow of the pyrolysis material and Pyrolysis coke through the gaseous pyrolysis inventory share what leads to better warming and in addition leads to a shorter degassing time, so that a high performance of the system is guaranteed.

Compression, forced promotion and post-compression of the Pyrolysis goods are carried out in an advantageous Ver Intermittent driving training.

The introduction of the pyrolysis material and the application the solid residues can easily be there by done that a tubular pyrolysis  given chamber on its entry and exit side if there are adjustable cross-sectional constrictions, so that there is grafting on the inlet and outlet side form the outflow of gaseous pyrolysis prevent products. Through the continuous feeding and compression of pyrolysis material becomes self-sealing grafting constantly renewed. It is also possible, on the outlet side the counter pressure to self tendency to clog with mechanical aids, such as. spring-loaded plates or in their we to generate similar components.

Tubular pyrolysis chambers are also advantageous a clear diameter between approx. 100-400 mm, the length / diameter ratio is greater than 10: 1 should be.

A batchwise, i.e. intermittent coercion promotion of the pyrolysis material or the densified solid residue also has the advantage that in cooperation with the pressure contact of the pyrolysis good to the chamber walls incrustations and caking of pyrolysis residues on the chamber walls by stän removed friction of the advancing pyrolysis material will. The pyrolysis chamber is at such an out leadership self-cleaning. It also contains none movable components, the long-term Be drove disturbances and especially regarding the Sealing and lubrication are difficult can.

The solid pyrolysis residues are advantageous in hot state (approx. 400 ° C) in a melting cyclone (Post-combustion chamber) and there under Oxygen supply burned or melted into slag Zen.  

The total energy content of the hot pyrolysis coke can be used directly.

When using pure oxygen or at least acidic Substance-enriched air must have a high nitrogen content the air are not heated, so that the Ab gas volume significantly reduced and exhaust gas cleaning technically good to control and cheaper design is.

The high one that occurs in low-temperature pyrolysis The carbon content of the residue is bad fabric-binding properties. This can still happen under supports that the pyrolysis material before compression harmful additives are added.

Another particular advantage is that the exit of the gaseous pyrolysis products from the pyrolysis chamber at the end of the conveyor line. In this case, the hot gaseous gases flow through Pyrolysis products on the one hand the pyrolysis in full Length, on the other hand, this makes the pyrolysis chamber depressurized only immediately before application, what the sealing of the pyrolysis chamber at the outlet page simplified. According to the current tion of the gaseous pyrolysis products and thereby conditional pressure drop along the pyrolysis chamber there are the highest pressures at the insertion side and ensure both quick warm-up tion as well as for quick degassing.

Optimal heat transfer through pressure contact, opti mated thermal conductivity by reducing the pores volume and additional volume heating by the gaseous pyrolysis products themselves are already him  mentioned advantages of pyrolysis according to the invention procedure for heating the pyrolysis material compared to the prior art. Through the Pyrolysis itself becomes the thermal conductivity of pyrolysis good constantly improved, especially in the contact zones of the walls, so that the pyro already preferred here areas, the heat is also generated by good warmth line to the interior areas that are not yet ready are pyrolyzed, pass on. An additional effect is given by the fact that the carbon-rich rest substances in the compressed or post-compressed state have much better heat conduction than the original original pyrolysis material. Compression according to the invention condition of pyrolysis material and residues as well as the stan pressure contact of the pyrolysis material with the chamber walls not only minimize the necessary dimensions the pyrolysis chamber, they also shorten the necessary Pyrolysis time considerably.

In mobile systems, it can be advantageous to sufficient density of undensified pyrolysis add a thermosetting, crosslinking binder, that the pyrolysis residues in a briquette-like, pressure-resistant condition, the dust proportions to a large extent integrated into the briquettes remain so that they can be burned elsewhere can be fed easily over longer distances. The dust-binding properties of the minor bandage quantities are also an advantage, since they keep the dust away from the pyrolysis gases, so that their cleaning is simplified and cheaper.

Due to the high flow rate of the con trolls exiting gaseous pyrolysis products can ge directly via an engine leads and used energetically.  

The hot exhaust gases from the Pyro's combustion lysis products (gas and coke) at 1200 ° C can be used to heat the pyrolysis chamber.

Can drive in the inventive Niedertemperaturpyrolysever the pyrolysis chamber, all belonging to the state of the art civic amenities - such as washes example Spaltgasbildner (crackers), dust filter, exhaust gas and the like - are subordinate.

Claims (11)

1. pyrolysis process for degassing organic substances, such as domestic, industrial waste and the like, in a heatable pyrolysis chamber, characterized in that the pyrolysis material is introduced into the pyro lysis chamber under compression and while maintaining a compressed state through the chamber cross section, the latter passes through that Heat is supplied to the pyrolysis well through the chamber walls which are in pressure contact with the compressed pyrolysis material, and that the gaseous pyrolysis products which form are removed at elevated pressure. 2. The method according to claim 1, characterized, that the pyrolysis chamber in its loading area ver gas-tight due to the compressed pyrolysis material is closed, and that they are in the outflow area of the gaseous pyrolysis products have an increased flow resisted by densification of the solid pyrolysis has residues. 3. The method according to claim 1, characterized, that the pyrolysis material by tubular pyrolysis chamber is promoted. 4. Method according to at least one of the preceding claims, characterized, that the supply of the pyrolysis material, its compression and the passage through the pyrolysis chamber intermittently rend.   5. The method according to at least one of the claims 1-3, characterized, that the supply of the pyrolysis material, its compression and its passage through the pyrolysis chamber continuously Lich done. 6. Method according to at least one of the preceding claims, characterized, that the solid pyrolysis residues before their end delivery to be compacted. 7. Procedure according to at least one of the preceding previous claims, characterized, that the uncooled solid pyrolysis residues (pyrolysis coke) are burned with the addition of oxygen. 8. Procedure according to at least one of the preceding claims made, characterized, that the exhaust gases from the combustion of the pyrolysis residues at least partially for heating the pyrolysis chamber be used. 9. The method according to at least one of the preceding claims, characterized, that the pyrolysis goods added pollutant-binding additives will give.   10. Procedure according to at least one of the preceding claims made, characterized, that the undensified pyrolysis binder is added. 11. The method according to claim 1, characterized, that the pyrolysis in the temperature range between 250 ° C and 500 ° C takes place.