DE4341820C2 - Method and device for the thermal treatment of sludges containing biomass and inorganic constituents - Google Patents

Description

The invention relates to a method for thermal treatment of sludges containing biomass and inorganic constituents men and an apparatus for performing the method.

DE 38 42 138 A1 describes a method for simultaneous Treatment of mechanically pre-dewatered sewage sludge and known dry biomass waste. Thereby biomass waste like waste paper or straw, first roughly shredded. Entwäs Fermented sewage sludge is mixed with the pre-shredded biomass mixed thoroughly. The mixture is pressed through a perforated die and the pellets obtained are dried. The dried ones Pellets are used thermally. The fuel in the form of the Dried pellets are intended for use in processes for the thermal utilization of dried sewage sludge suitable his. As a process for the thermal utilization of getrock high-temperature combustion in one Melting chamber injection firing, the low temperature smoldering with oil production from the condensed carbonization gas and the recycling company as a fuel in asphalt mixing plants with admixture of Ash in the asphalt or bitumen mixture for road construction called.

DE 41 09 063 A1 describes a process for the simultaneous utilization of lumpy and flowable combustible waste materials and residues. Combustible waste materials and residues include waste oil fractions and solvents contaminated with heavy metals or with organochlorine components, contaminated oil-water emulsions, dust-containing oils, tars and tank residues, plastic waste, sewage sludge, shredder residues, used tires, other carbon-containing industrial residues or household waste. The recovery takes place by combining a moving bed gasification in a shaft with an autothermal flame reaction stage and the formation of a common slag bath. The lumpy waste and residues are used in gasification of moving beds. In the autothermal flame reaction stage, the flowable waste materials and residues and possibly flowable fuels react with an oxygen-containing combustion or gasification agent. The gas formed by the moving bed gasification and the remaining solid residues enter a reaction chamber of the flame reaction stage. The gases formed in the flame reaction stage are reacted with the gas formed in the moving bed gasification and the remaining residues, the reaction conditions being set so that a CO and H ₂ -rich raw gas is formed and that at the bottom of the reaction chamber Forms slag bath. The hot raw gas passes together with the molten slag via a drain device into a cooling zone arranged below the reaction chamber, in which the raw gas and the slag are cooled and the slag is granulated. Temperatures of 1400 degrees Celsius to 1700 degrees Celsius prevail in the reaction chamber mentioned. The mineral components of the feedstocks are transferred to the slag, which is discharged as granules from a glass-like structure that is leach-proof against atmospheric water.

The object of the invention is to provide a method and a device of the aforementioned type to create the kind in which on the one hand the energy content of the Biomass and the sludge containing inorganic components me is well utilized and on the other hand the pollution of the environment, especially with heavy metals, is kept as low as possible.

The object is achieved by a process for the thermal treatment of sludges containing biomass and inorganic constituents, in which

• Biomasses and sludges are processed into pellets I in a first pelletizing unit 5 ,
• the pellets I obtained from a smoldering are placed in a gasifier 7 for the production of smoked coke and smoldering gases,
• - The Schwelkoks or in a pelletizing unit 6 te te and containing Schwelkoks containing pellets II is / are thermally treated in a first partial combustion stage 9 with oxygen-containing gas at a temperature of about 900 degrees Celsius and
• - The solid products of the partial combustion stage 9 are given directly to a second combustion stage 10 with the formation of a glassy slag and with the addition of an oxygen-containing gas and a further fuel gas at a temperature of approximately 1500 degrees Celsius.

Preferred embodiments of the method according to the invention result from the subclaims.

The invention relates also a device for solving the task with the inventive features of claim 14.

The invention is explained below with reference to the figures.

Show it:

Fig. 1 is a flow diagram of the method according to the invention and

Fig. 2 is a flow diagram of a preferred embodiment of the method according to the invention.

The reversible water absorption capacity of the capillary-active, shredded dry matter of vegetable origin, ( 2 ) = straw, autumn leaves, forest residues, waste paper (renewable biomass), mixed with organic water sludge ( 1 ) = sewage sludge, animal manure or inorganic sediment sludge ( 3 ) = red sludge , Dredging silt, take out a blotter, the ballast water also on relatively thin sludges, so that within minutes it is puncture-resistant and bad smells are decimated.

Further kneading creates a malleable mixture that dries faster in the air at room temperature ( 4 ) because the drying agents act like a wick. Such dry moldings show interesting mechanical properties: as composites, the dry matter of the originally aqueous sludge has now homogeneously embedded the crushed dry matter. They give such moldings a special kind of elastic strength. For example, they do not break when dropped onto solid surfaces, they have sufficient abrasion resistance so that they can be easily stored and transported. They are fine-porous and therefore capillary-hygroscopic with excellent adsorption capacity against gaseous substances.

They also put a new, not fossil, son is man-made solid fuel, whose Calorific value by the sum of the individual components give is. The component combination can be targeted be chosen right.

Because of their stiffness, dry pellets ( 5 ) and ( 6 ) represent a favored form of these new fuels as starting materials for gasification or combustion, in particular they are suitable for smoldering and sintering for use in flushing gas processes and fluidized beds or on the traveling grate.

The gasification ( 7 ) of the pellets I ( 5 ) from the regrowth of the biomass with the adjusted moisture takes place at around 600 ° C. and with a stoichiometric supply of air in the purge gas process. The products of this gasification are:

• - Smoldering (water) gas that supplies the process heat of the gasifier and its waste heat recovery ( 8 ) and also the ignition energy for the autothermal combustion stage ( 9 ) stage 1. ) And the heating gas of the glass melt ( 10 ), stage 2. ). In these two stages of combustion, oxidizing is carried out, e.g. B. allow the mineral components of the dredging silt to form the oxidic composition of a glass melt. The glasses immobilize heavy metal compounds and are largely commercially available.
• - Smoke coke, which as a high-energy heating component of pellets II ( 6 ) increases their own heat-emitting share of organic material for autothermal combustion. The ash formed here as an intermediate represents the already high-temperature, practically C-free base substance for glass formation.

The exhaust gases from ( 9 ) and ( 10 ) reach cooling after gaining heat through exchanger in the solid absorption section ( 11 ), in particular for Hg and As binding, which is formed by a loose stratification of dry moldings according to ( 6 ).

If necessary, an additional 2-stage exhaust gas purification is then carried out in ( 12 ), which is able to also bind CO ₂ from the flue gas.

Claims (15)

1. Process for the thermal treatment of biomass and sludges containing organic constituents, characterized in that
Biomasses and sludges are processed into pellets I in a first pelletizing unit 5 ,
the pellets I obtained a smoldering in a gasifier 7 for the production of smoked coke and smoldering gases are given up,
the smoked coke or in a pelletizing unit 6 and pellets II containing smoked coke is / are thermally treated in a first partial combustion stage 9 with oxygen-containing gas at a temperature of approximately 900 degrees Celsius and
the solid products of the partial combustion stage 9 are given up directly in a second combustion stage 10 with the formation of a glassy slag and with the addition of a gas containing oxygen and a further fuel gas at a temperature of approximately 1500 degrees Celsius. 2. The method according to claim 1, characterized in that in the pelletizing unit 5 additionally dried biomass 2 is added from a dryer 4 . 3. The method according to claim 1, characterized in that the pellets II are produced by mixing and pelletizing coke and dried biomass 2 and / or inorganic sediment sludge 3 . 4. The method according to claim 3, characterized in that the carbonization gas from the carburetor 7 in the combustion stage 10 and if necessary in the partial combustion stage 9 is used as a further fuel gas. 5. The method according to any one of the preceding claims, characterized characterized that as biomass straw, autumn leaves, wood and / or waste paper can be used. 6. The method according to any one of the preceding claims, characterized characterized as sewage sludge, animal manure, Fruit mashing, inorganic sediment sludge, red mud and / or dredging silt are used. 7. The method according to any one of the preceding claims, characterized in that the sludge undergoes material conditioning before use, so that the solid product from the partial combustion stage 9 has a specific oxidic composition and in the combustion stage 10 as a slag glass or ceramic products become. 8. The method according to any one of the preceding claims, characterized in that a kneading mixing of the biomass and sludge takes place in the pelletizing aggregate 5 and the pelletizing unit 6 . 9. The method according to any one of the preceding claims, characterized in that fuel pellets I produced in such an amount and subjected to a smoldering in the gasifier 7 that excess fuel gas is produced which is supplied to the power generation as fuel gas. 10. The method according to any one of the preceding claims, characterized in that the waste heat 8 from the gasifier 7 , the partial combustion furnace 9 and the combustion furnace 10 is used to generate electricity by means of steam. 11. The method according to any one of the preceding claims, characterized in that the exhaust gases from the partial combustion stage 9 and the combustion stage 10 are subjected to exhaust gas purification. 12. The method according to claim 11, characterized in that a fixed absorption section 11 , in particular for the binding of mercury and arsenic, is provided for exhaust gas purification, in which pellets II are used as exhaust gas purification compositions. 13. The method according to claim 11 or claim 12, characterized in that a two-stage exhaust gas purification 12 is provided, in which the acidic exhaust gas components are absorbed in a first stage and in a second stage the CO ₂ from the exhaust gas is bound alkaline. 14. An apparatus for performing the method according to one of the preceding claims, comprising
a first pelletizing unit 5 , in which biomass and sludge are processed into pellets I,
a carburetor 7 , in which the pellets I are subjected to a welding treatment to obtain carbon dioxide and carbonization gases,
a pelletizing unit 6 , in which pellets II containing smoked coke are produced,
a first partial combustion furnace 9 , in which the Pel lets II are thermally treated with oxygen-containing gas at a temperature of approximately 900 degrees Celsius, and
a second incinerator 10 , in which the solid products from the partial incinerator 9 are thermally treated to form a glassy slag and with the addition of an oxygen-containing gas and another fuel gas at a temperature of approximately 1500 degrees Celsius. 15. The apparatus according to claim 14, characterized in that it for cleaning the exhaust gases from the first partial combustion furnace 9 and the second combustion furnace 10 has a fixed absorption path 11 , in particular for the absorption of mercury and arsenic, and / or a two-stage exhaust gas purification 12 , especially for binding carbon dioxide.