DE2944989A1 - Purificn. of gases from pyrolysis of wastes - with reduced pollution from disposal of used absorbents - Google Patents

Abstract

Process is claimed for the removal of harmful ducts and gases from the gases produced in the pyrolysis of waste matls., e.g. household refuse. After removal of pyrolysis coke, the gases are passed in intimate contact through a layer of physical or chemical absorbent, at a density of at least 1 kg/cubic m, and a temp. pref. above 250 deg.C. The absorbent may be in a fixed bed, or in a rotating ball mill, or in a fluidized bed. A filter aid such as powdered pumice may be used to lighten the absorbent layer. Suitable absorbents for acid substances are lime (added e.g. as milk of lime) and haematite. Pref. absorbents for basic substances are montmorillonite and bentonite. Relative to the usual process, in which absorbents are added to the pyrolysis reactor itself, the process requires less absorbent; and the separate streams of contaminated adsorbent and uncontaminated coke can be disposed of with less pollution of ground water than the usual mixed stream (coke being in larger amt.).

Description

Procedure for cleaning

Pyrolysis gases The earth connection relates to a method for purifying gases containing pollutants produced during the pyrolysis of waste materials by heating them up arise at the decomposition temperature and separated from the low-temperature coke formed have been, with dust-like pollutants separated from the carbonization gas and inorganic ones as well as organic substances through chemical and / or physical bonding or absorption removed.

Sch, relgas produced by pyrolysis of waste materials usually contains a number of pollutants, such as dust, compounds of nitrogen, chlorine, sulfur and fluorine, cyano compounds, phenols and the like, as well as hydrocarbons. At the Purification of such carbonization gases has hitherto been carried out in such a way that the ReaktQr, in which the pyrolysis is carried out, a basic binder to bind the acidic contaminants are added. In the case of pyrolysis using a rotary tube, for example in addition to the waste to be treated, hydrated lime is added to the rotary kiln, which binds the acidic components. This method has the disadvantage that a relatively large amounts of lime are used for binding acidic pollutants must become. In addition, the lime, which is polluted with pollutants, is used together with the smoldering coke taken from the rotary kiln, so that when the low-temperature coke is stored in the open air Salts are washed out, which leads to groundwater and surface water pollution to lead.

The invention is based on the object of a method of the input called type to create, which is more environmentally friendly and with a lower Amount of binders to bind pollutants.

The solution to this problem is to be seen in the fact that the carbonization gas so and at such a point a binder is added in finely divided form, that the binder and the pollutants bound by it practically not get into the smoldering coke that the added binder and that already Bound pollutants are concentrated to a density of at least 103 g / m3, that the carbonization gas is brought into intimate contact with the concentrated binder is, and that the temperature of the carbonization gas at least from the pyrolysis reaction chamber to after the zone containing the concentrated binder above and and is preferably kept above 250.degree.

For the purposes of the invention, pyrolysis is the degassing process to understand in which the decomposition of waste materials to a large extent takes place by air / oxygen, the heat being brought to the material to be treated from the outside as well as the gasification processes in which those responsible for thermal decomposition the waste materials generate the necessary heat through partial combustion in the reaction chamber will.

For the purposes of the invention, binders are not limited to substances understand chemical bonds with pollutants, but also absorbents and other substances that physically bind pollutants.

The term divided is intended to be both a powdery and a mean an atomized or aerosol state, such as in atomization from liquids such as milk of lime or caustic soda.

The binder is preferably concentrated to at least one layer, through which the carbonization gas is passed. It has been shown that on this Way much shorter contact times for the binding of the pollutants to the binder are required as if the pollutants with the Binder only in the suspension state in the carbonization gas in contact with one another come.

Alternatively, the binder can be concentrated in a gugelmallrle and the carbonization gas can be passed through the ball mill.

The layers of the binding agent formed on the balls come in the process in a similar intimate contact with the pollutants as when passing them through by a binder layer, preferably the binder is applied to at least one Place behind the carbonization gas from let the pyrolysis reaction chamber added.

In this way it is avoided with certainty that proportions of the binder get into the smoldering coke and are discharged with this.

A further development is to be seen in the fact that the binder with the Carbonization gas and the entrained dust is swirled around the binding reaction accelerate. The turbulence also allows a high density of dust in the Generate pyrolysis gas to be cleaned, approximately between 103 and 5,104g / m3. Through the Whirling, a good preliminary separation is already achieved and - if one Binder layer is to be generated - a homogeneous layer structure is generated.

A filter aid is preferably added to the binding agent, z. B. pumice grains with a grain size of more than 10 Plum build a Layer to make it easier.

The carbonization gas can also contain several binders for different Pollutants are added, e.g. hydrated lime as a blade for acidic pollutants and / or hematite, the latter for binding hydrogen sulfide, and as a binding agent iiir basic Pollutants acidic earth, z. B. Montmorilonite and Bentonite.

An advantageous further development consists in adding the basic binder Add water, at most in such an amount that the fine distribution of the binder is not yet impaired. This particularly increases the bond accelerated by hydrogen chloride and certain other acidic constituents.

The basic binders can be applied to porous supports that increase the surface area of the binder.

An advantageous further development consists in the binding agent Schwelkoke or add carbon dioxide dust from the reaction room.

In this way, the need for binder can be reduced because Smoldering coke in finely divided form itself as a binding agent or agglomeration agent works.

If different binders are used, these are recommended added at spatially separate locations in order to avoid that the binders with each other react yourself. It is best to proceed in such a way that a further binding agent is only started is added to such a point where the binding reaction of the previously added Binder has already reached a desired level.

It is also advantageous that a concentration is added to each addition of binder of the binder and optionally at least partial discharge of the same he follows.

If the flow of the carbonization gas is supported by a fan, it is preferable to arrange the fan so that it hits the carbonization gas up to the separation of the powdery products and optionally the condensation products Indent and then a pressure is exerted0 on this is quiet achieves that the risk of hars formation ii suction and the thermal The load on the induced draft is smaller and, above all, the risk of the dreaded acid corrosion is bypassed. Another advantage is that after the induced draft as well as the overpressure prevails and thus the risk of air ingress into the behind the fan Parts of a system no longer exist. Therefore need the tightness of the after The system components connected to the fan are no longer subject to such high demands to become.

According to another development, the condensable Products by gradually cooling the 8chwolgasee behind the concentrated Binder-containing zone deposited in a fractionated manner. That brings the advantage with the fact that if the condensable products are reused, none fractional distillation is more required.

An optimal embodiment of the method is achieved in that the addition of the binder as a function of a parameter of the cleaned carbonization gas, preferably the HOl value is regulated.

According to another characteristic, the binder becomes the concentrated one Binder containing zone discharged. This can be ongoing or from time to time done so that there is always a reactive binder available.

Binder removed can be returned to a binder inlet as it promotes the agglomeration of dust particles.

The invention is based on an exemplary embodiment below a schematic drawing additionally described.

The single figure shows a flow chart of the process flow at a pyrolysis plant for the decomposition of waste materials.

Example In an airtight rotary kiln 1 are Waste materials, such as household waste, sewage waste and hazardous waste, are placed in inlet 2 and carbonized.

The rotary kiln is heated from the outside and the treated waste materials decompose into solid substances, namely smoldering coke, which flows through the solid matter 3 got out of the rotary kiln, and in carbonization gases, which the rotary kiln leaves via the gas outlet 4. This is via a connecting pipe 5 to the inlet 6 of a sorption reactor 7, which forms a ball mill, on the balls the solid components get caught in the carbonization gas and form a layer, on which the carbonization gas hits. It gets between those released by the balls tight spaces and thus comes into intimate contact with the one adhering to the balls Coating. Instead of a ball mill, other sorption devices can also be used can be used, such as rotating sieve belts, sieve drums, filter surface and the like. Care should be taken to remove the make coat from time to time or is continuously renewed so that there is always reactive binding agent in the sorption reactor is available.

Immediately behind the gas outlet 4 of the rotary kiln 1 is via a Feed device 8 ground hydrated lime or milk of lime finely divided as a binder or atomized, the binder in the connecting pipe 5 as possible Turbulent is fed in to accelerate the binding of acidic pollutants to reach the hydrated lime.

The use of veal milk has because of its water content The advantage is that the binding of hydrogen chloride is facilitated. However, this must be done Make sure that the water in the milk of lime layers before it reaches the binder is evaporated in order to avoid clogging and sticking of the same.

Al-basic binders are particularly suitable basic calcium compounds such as quicklime, calcium carbonate, hydrated lime, calcium oxide, basic magnesium compounds like magnesium carbonate, magnesium oxide, magnesium hydroxide, dolomite, as well as basic ones Sodium and potassium compounds such as sodium carbonate, sodium hydroxide and the corresponding Potassium compounds, also red mud and clay.

As a binder for hydrogen sulfide and compounds containing sulfur iron oxides, especially hematite, are suitable.

As shown by the connecting line 10, carbonized coke can also be used removed from the rotary kiln 1 and added as a binder. The usage of smoldering coke, which must of course be ground, enables the reduction of the Addition of foreign binders.

From the sorption reactor 7 is the used binder, on which acidic pollutants are bound by the discharge 11 to the landfill or for further processing letted out.

The carbonization gases leaving the sorption reactor 7 via the gas outlet 12, which still contain basic pollutants in addition to other pollutants, wer'derian one second sorption reactor 13 forwarded, which is similar to the sorption reactor 7 can be. Behind the gas outlet 12 of the same, an acidic binder is added, such as acidic fuller's earth, bentonite or montmorilonite, about ammonia or to bind other basic pollutants.

The used acidic binder with the pollutants bound to it passes through the outlet 14 to the landfill or for further processing.

The amount of binder to be added depends on the content of the the pollutants to be separated in the carbonization gas and the required degree of purity of the clean gas. It can therefore fluctuate over a wide range. Additions are preferred in the Close to the stoichiometric ratio, roughly in the range 0.3 to 3.

However, it is also possible to work overstoichiometrically and that Reaction product, which contains unreacted starting material, for further Implementation of the binders to use again.

Sorption reactors for the purposes of the invention are known per se.

It has been shown that a substantial part of the pollutants only is bound in the binder layer and not already when the carbonization gas comes into contact with the finely divided binder.

It is therefore essential to the invention to ensure that the binder is sufficiently concentrated after its addition into the carbonization gas stream, preferably to a density of 1O3g / m3 and even better to a density of more than 5 x 104g / m3, to bring about the desired binding of the pollutants.

The material removed through the outlets 11 and 14 consumed a ver The binder layer is deposited separately from the smoldering coca or in another. Fabrics incorporated as an aggregate.

The separate landfill has the advantage that the used binder layer, which contains a relatively high proportion of salts and heavy metals, however is produced in significantly smaller quantities than the smoldering coke, without polluting the groundwater can be stored. On the other hand, the smoldering coke contains noticeably fewer pollutants, which may indicate soil pollution.

The gas outlet 15 of the second sorption reactor 13 leads to a quearer and / or KUhlor 16, in which the temperature of the carbonization gas is gradually lowered is, eo that the substances capable of condensation contained in the carbonization gas are fractionated excreted and further treated in a targeted manner or used immediately since dust and other pollutants have already been eliminated. The carbonization gas is raised in the quenching device using water or quenching oil cooled to a temperature of 1000 to 1300 C. The pyrolysate produced can also can be partially returned to the washing circuit of the oil squeegee.

It is characterized by a low chlorine and sulfur content, since these compounds have already been deposited beforehand.

The temperature of the carbonization gas should be from the gas outlet 4 of the rotary kiln 1 to the entrance of the Ouenscher and / or cooler 16 at a temperature above 20000 and better still above 25000 are kept to a partial condensation of the Avoid condensation products in this branch of the plant.

At the outlet 17 of the cross cutter and / or cooler. 16 is an induced draft fan 18 connected. From the outlet 19 of the same to the outlet of the plant there is a Overpressure, so that there is no danger of air ingress in this part of the system exists, which is especially important in the case of further treatment of the carbonization gas for recovery of light oil is important. The discharge organs in this aftertreatment line the gardening system no longer have to have the high tightness requirements as in the negative pressure part of the system.

The pyrolysis gas is partially branched off from outlet 19 and used for heating of the rotary kiln used, on the other hand it can be a combustion chamber for the purpose the steam or a downstream power generation or any other use are fed. If energy is used, falls in the pyrolysis system no Water, which had to be treated further. The exhaust gas of the purified pyrolysis gas can be blown directly into the open using the sensible heat, whereby the water vapor is removed with the exhaust gas.

If the pyrolysis gas has sufficient amounts of light oil (pyrolysate) contains, which bring a revenue that is used outside of the pyrolysis plant the pyrolysis gas in a Kohler 20 becomes as deep as economical cooled reasonably below the water dew point. The resulting light oil and the Water condensate must then be separated from one another. That freed from water vapor Pyrolysis gas has a significantly higher calorific value than that of household waste as the starting material 4000 to 6500 kcal / Nm3 is.

The method described above is simpler than known processes and also manages with a lower addition of binder. Further it has been shown that the addition of hydrated lime reduces the carbonization gas entrained dust can also be separated more easily.

Claims (21)

Patents n # ri1che 1. Process for cleaning so-pollutant-containing Gases produced during the pyrolysis of waste materials by heating them to the decomposition temperature arise and which have been separated from the low-temperature coke formed, whereby from the carbonization gas separated dust-like pollutants and inorganic and organic Pollutants removed by chemical and / or physical bonding or absorption be, by noting that the carbonization gas so and at one such a point a binder is added in finely divided form that the binder and the pollutants bound by this practically do not get into the smoldering coke, that the added binder and the pollutants already bound by it is concentrated to a density of at least 103 g / m3 that the carbonization gases in intimate contact with the concentrated binder is brought, and that the temperature of the carbonization gas at least from the pyrolysis reaction chamber to after the concentrated Binder-containing zone above 2000 C and preferably above 2500 C is held. 2. The method according to claim 1, characterized in that g e k e n n 8 e i c h -n e t that the binder is concentrated to at least one layer through which the Carbonization gas is passed through. 3. The method according to claim 1, characterized in that g e k e n n z e i c h -n e t that the binding agent is concentrated in a Eugolma mill and that the carbonization gas passed through the ball mill will. 4. The method according to claim 1 to 3, characterized in that g e k e n n -z e i c h n e t that the binding agent at least at one point behind the Schwelgaa outlet the pyrolysis reaction room is added. 5. The method according to claim 1 to 4, characterized in that g e k e n n -z e i c This means that the binder swirls with the carbonization gas and the dust that is carried along will. 6. The method according to claim 2 to 5, characterized in that g e k e n n -z e i c Not that a filter aid is added to the binder to make it easier of building a layer. 7. The method according to claim 6, characterized in that g e k e n n z e i c h -n e t that pumice stone grains with a grain size greater than 10 are used as a piltering aid will. 8. The method according to claim 1 to 7, characterized in that g e k e n n -z e i c h Not that the carbonization gases contain several binders for different pollutants be added. 9. The method according to claim 1 to 8, characterized in that g e k e n n -, z e i c Not that the binding agent for acidic pollutants is hydrated lime and / or hematite is used. 10. The method according to claim 1 to 9, characterized in that g e k e n n -z e i c Not that acidic earths are preferred as binders for basic pollutants Montmorilonite and Bentonite can be used. 11. The method according to claim 10, characterized in that g e k e a n s e i c h -n e t that water is added to the basic binder, at most in one such an amount that the fine distribution of the binder is not yet impaired will. 12. The method according to claim 10 or 11, characterized in that; g e k e n n -z e i c h n e t that the basic binders are applied to porous supports, which increase the surface area of the basic binder. 13. The method according to claim 1 to 12, characterized in that g e k e n n -1 e i c h n e t that the binding agent ground coke or coke dust from the Pyrolysis reaction space is added. 14. The method according to claim 8, characterized in that g e k e n n s e i c h -n e t that the various binders are added at spatially separate locations. 15. The method according to claim 8 and 14, characterized in that g e k e n n -z e i c h n e t that a further binding agent is only added at such a point, where the binding reaction of the previously added binding agent has reached an extreme level has reached. 16. The method according to claim 14 or 15, characterized in that g e k e n n -s e i c h n e t that on every addition of binder a concentration of binder and if necessary, at least partial discharge of the same takes place. 17. The method according to claim 1 to 16, wherein the flow of the carbonization gas is supported by a fan, by the fact that from Blower on the Carbonization gas up to the separation of the powdery products and, if appropriate, the condensation products output a train and then a pressure will. 18. The method according to claim 1 to 17, characterized in that g e k e n n -z e i c h n e t that the condensable products by stepwise cooling of the Carbonization gas behind the last zone containing a concentrated binder are deposited fractionally. 19. The method according to claim 1 to 18, characterized in that g e k e n n -z e i c h n e t that the addition of the binder as a function of a parameter of the purified Carbonization gas, preferably the HCl value, is regulated. 20. The method according to claim 1 to 19, characterized in that g e k e n n -z ei c That is, the binder from the zone containing the concentrated binder is paid off. 21. The method as claimed in claim 20, characterized in that it is e k e n n z e i c h -n e t that discharged binder is returned to a binder inlet will.