EP0257018A2 - Process for the thermal use of wastes and/or waste fuels - Google Patents

Abstract

The process involves gasifying the wastes and/or waste fuels, by feeding them to gasifying reactors (3, 4) heated directly by gas and/or oil, and subsequently burning the gases formed. Part of the flue gases from the downstream combustion chamber (5) are returned under pressure to one of the gasifying reactors (3), which is operated at temperatures between 500 and 1200 DEG C, preferably at temperatures between 700 and 1200 DEG C. <IMAGE>

Description

The invention relates to a method for the thermal utilization of waste and / or waste fuels by gasification and subsequent combustion of the gases formed.

Gasification reactors with which residues containing heavy metals, for example in the chemical industry, can also be processed can be found, for example, in AT-PS 379 618. In this known gasification reactor, heavy metal-containing waste is added to a secondary gas reaction zone and in this way it is achieved that such waste can be discharged together with the slag after the slag bath has solidified. With such reactors, it is therefore necessary to work at a relatively high temperature in order to ensure a liquid slag bath, and for a number of wastes which are problematic in terms of disposal, gasification at such high temperatures is not economical. Particularly for plastic waste and heavy metal-containing waste that can be decomposed at a much lower temperature, it could be sensibly processed even at a lower temperature. In the known gasification reactors, so-called weak gases are produced, which have a calorific value, which makes it possible to burn these gases at least together with an auxiliary furnace. The flue gases produced in the subsequent combustion for the purpose of energy generation cannot be used directly in such high-temperature gasifiers, so that valuable energy contained in the flue gases is lost.

The invention now aims to make better use of the flue gases withdrawn from a combustion chamber for energy generation and to create an economical method which a number of wastes that are not easy to dispose of, such as waste containing heavy metals or plastics, can be thermally recycled. To achieve this object, the invention essentially consists in that the waste and / or waste fuels are fed to a gasification reactor which is directly heated with gas and / or oil, that the gases withdrawn from the gasification reactor are fed to a combustion chamber for energy, in particular steam generation, and in that some of the flue gases from the combustion chamber are returned to the gasification reactor under pressure. Because the flue gases of the combustion chamber are returned to the gasification reactor, extensive regulation and control of the gasification behavior can be achieved, in particular when carrying out a process in which the temperature is significantly lower than that of high-temperature gasification. The recirculation of flue gases leads to a reduction in the temperature in the carburetor due to the reaction equilibrium between CO and CO₂ in the gas phase, but on the other hand the advantage is achieved that a reducing mileage can be set in the carburetor and the CO supply in the carburetor Regulation can be subjected. The process according to the invention is therefore advantageously carried out in such a way that the temperature in the gasification reactor is kept between 500 and 1200 ° C., preferably between 700 and 1200 ° C., with the fact that the flue gases of the combustion chamber are returned to the gasification reactor under pressure, the regulation of the gasification behavior and also the setting of the gasification zone can be ensured in a simple manner by recirculating the flue gases in the gasification reactor in at least two different zones. A recirculation of the flue gas close to the task of the waste or waste fuels can be used to pre-dry and preheat this waste, whereby the desired moisture content of the waste or waste fuels can also be returned by means of a corresponding steam return to such a medium-temperature gasification reactor can be influenced, which in turn can improve the gasification behavior. By simultaneously recirculating the flue gas at the end of the feed and close to the burners, the height of the gasification zone can be shifted to such an extent that the gasification zone is set immediately adjacent to the outlets for the lean gases which are provided separately.

In a particularly simple manner, the method according to the invention can be carried out in such a way that loose fuel is supplied compressed to the gasification reactor via a feed screw, alternatively lumpy fuels can be supplied to the gasification reactor as bulk material or fuel compressed into bales can be supplied via a push-in device.

The pressure of the flue gases required for the recirculation in different levels of the medium-temperature gasifier can be achieved in a simple manner by using the flue gases under the pressure of the induced draft fan for the pre-drying of fuels for the gasifier.

In order to adjust the position of the gasification zone and a gasification behavior that is adapted to the respective waste or waste fuel, the flue gases are advantageously returned to the carburetor via an adjustable throttle element for setting the reducing environment and the CO₂ supply in the gasifier.

For the operation of such a system, it is advantageous if energy can be made available continuously. Since there is not always problem waste which can be converted into usable gases in the case of medium-temperature gasification, it is advantageous to design the system so flexibly that it can also be operated without an upstream gasifier. As soon as a carburetor is switched off, starting up such carburettors is generally difficult.

It is therefore advantageous in the context of the method according to the invention that the flue gases are used to preheat the carburetor when starting, which means that starting a parked carburetor can be significantly accelerated.

In addition to such a medium-temperature gasification reactor, a known high-temperature gasification reactor, such as, for example, a reactor according to AT-PS 379 618, can generally also be provided in order to process or dispose of waste of a different type and to be processed at a higher temperature. A flue gas recirculation for preheating when starting is also advantageous in such devices, but the recirculation of flue gases is not readily possible with a high-temperature gasifier, since this recirculation could lead to a lowering of the required high temperatures in consideration of the Boudouard balance.

The gases leaving the gasification reactor are at the temperature set in the gasification reactor and such a temperature can subsequently lead to undesirably high combustion temperatures in the combustion chamber. It is therefore advantageous to proceed in such a way that the combustible gases drawn off from the carburetor are conducted via heat exchangers of the boiler of the steam generation, as a result of which the weak gases can be pre-cooled while simultaneously using their sensible heat. The lean gases leaving the carburetor can be fed to a gas conditioning stage of conventional design to improve their combustion behavior. The recycling of flue gases can also be advantageous in the context of such a downstream gas conditioning stage and is particularly suitable for preheating and / or adjusting the CO₂ supply in the gas conditioning stage.

Another control option in the context of medium-temperature gasification is that part of the steam generated is returned to the gasification reactor. In order to improve the predrying of the fuel supplied to the gasification reactor, in particular the waste fuels or the wastes, the setting of a certain moisture level for these waste fuels or wastes can be advantageous. In the case of sufficiently moist fuels, the predrying can directly create a corresponding steam atmosphere with the hot flue gases, which facilitates the drying of such waste fuels. In addition, the steam return to the gasifier can be carried out together with the flue gases or adjacent to the flue gases, as a result of which the position of the gasification zone within the gasification reactor can also be adjusted.

The invention is explained in more detail below on the basis of exemplary embodiments schematically illustrated in the drawing. 1 shows a schematic block circuit diagram of a device for the thermal utilization of waste or waste fuels, in which a medium-temperature gasification is provided in addition to high-temperature gasification; 2 shows a schematic representation of a device according to FIG. 1 which only has a medium-temperature gasification; and FIG. 3 shows a modified embodiment in which only high-pressure gasification is provided, the low gases of which, however, are conducted via a gas conditioner supplied with flue gases.

In Figure 1, the supply lines for materials to be recycled are indicated schematically. Solid fuel or waste fuel is added via a line 1 and additional fuels, in particular gas or oil, are supplied for auxiliary firing via a line 2. These additional fuels are a medium-temperature gasification reactor 3, a high-temperature gasification reactor 4 and the combustion chamber 5 supplied for energy generation, in particular for steam generation in the boiler 6. The waste fuels must first be gasified and for this purpose the feed line 1 only opens to the medium-temperature gasification or the high-temperature gasification. Problem wastes, such as special waste, heavy metal-containing wastes or plastic wastes, can be fed to the high-temperature gasification 4 or the medium-temperature gasification 3 via the line 7 indicated by dashed lines, depending on the nature of these wastes.

The combustion air is introduced via a line system 8 and is made available to the two gasification reactors as well as to the combustion chamber 5. The combustion air can be preheated via a heat exchanger 9 in the smoke outlet after a possibly provided flue gas scrubbing 10, for which purpose a heat exchanger bypass 11 is provided.

The high-temperature gasification 4 is designed in a known manner and the liquid slag can be drawn off via a slag discharge 12. The low-temperature gas leaving the high-temperature gasification passes via a line 13 into a gas conditioning stage 14, which can contain, for example, a coke bed.

The fumes extracted from the combustion chamber 5 are drawn off via an induced draft fan 15 and in this way pressurized. The pressurized warm flue gas leaving the boiler can be returned via line 16 to the medium-temperature gasifier 3, the return within this reactor being able to take place at several levels in order to adjust the gasification behavior. The lean gas leaving the medium-temperature gasifier either passes directly into the combustion chamber via a line 17 5 or via the branch line 18 and via the gas conditioning stage 14 into the combustion chamber 5.

The weak gases of the high-temperature gasification 4 and the medium-temperature gasification 3, which are drawn off via the lines 13 and 17, can, if necessary, be cooled via a heat exchanger 19 which is connected to the jacket of the boiler 6, in which steam is generated. The steam of this boiler 6 can be used for energy generation. A portion of this steam returns via line 20 to medium-temperature gasification 3 or to high-temperature gasification 4. In high-temperature gasification 4, such steam will generally be necessary. In medium-temperature gasification 3, the return of steam is particularly suitable for better adjustment of the gasification behavior and to adjust the moisture content of the waste used. Ash is discharged from the medium temperature gasification stage 3 via the ash discharge 21.

The conventional flue gas scrubber 10 can be equipped with feed water lines 22 and return lines 23.

The medium-temperature gasification reactor can be fired in a simple manner with gas and / or oil, with the gasification of solid fuels or waste taking place in the temperature range between 500 and 1200 ° C. and preferably between 700 and 1200 ° C.

The flue gas recirculation takes place with the overpressure of the induced draft fan and enables the fuel to dry and create additional control options by influencing the reducing mileus and the temperature profile in the reactor.

In such a medium-temperature gasifier, solid fuels can be supplied by feed screws in the case of loose fuels and in the case of briquetted or lumpy fuels by a feed device for bulk material. Fuel pressed into bales, in particular fuel from waste, can be introduced by means of an insertion device.

The high-temperature gasification can be carried out according to known methods, and the gas conditioning, the firing and the flue gas scrubbing can also be carried out using known methods.

By returning the flue gas to the boiler and from the pressure side of the induced draft fan, the fuel can be predried and the reducing mileage and the CO₂ supply in the medium-temperature gasification can be regulated. The preheating of the gas conditioning is primarily important when starting up the plant, since the temperature of the lean gases leaving the gasification reactor is consequently sufficiently high.

Lean gas from different gasification systems can be produced in the same furnace with additional fuels. The combustion chamber 5 can thus be designed universally and only a steam generating boiler 6 is required. The lean gas lines of the two carburettors can be switched on and off as required and fed to the furnace with or without gas conditioning. The boiler output can be kept independent of the connection of the carburetor, which ensures a continuous energy supply.

The start-up difficulties of carburetors in normal boiler operation when switching on a carburetor can be reduced in that the carburetor before loading the Firing with additional fuels are heated and then switched on.

Problem wastes, such as liquid, pasteuse, solid wastes, some with high heavy metal contents, as well as temperature-resistant organic substances can optionally be processed in high-temperature gasification.

Fuel from garbage bales from a waste treatment facility, like lumpy or loose waste fuels, can be used in medium-temperature gasification. It is also possible to introduce dewatered sewage sludge into the medium-temperature gasification without any problems, in which case the flue gas recirculation is particularly advantageous for predrying. The medium temperature gasification can work continuously or discontinuously.

In the construction of the system according to FIG. 2, only a medium-temperature gasifier 3 is provided, the rest of the reference numerals from FIG. 1 being retained. In the embodiment according to FIG. 2, the optional supply of waste that is difficult to dispose of has not been drawn in, but can easily be provided in addition. The embodiment according to FIG. 2 also differs from FIG. 1 in that the flue gas recirculation is only carried out to the medium-temperature gasification reactor, but not to the gas conditioning 4. The gas conditioning 14 is thus used directly, just like the heat exchanger 19, for cooling the lean gas withdrawn via the line 17 before this lean gas is fed to the combustion chamber 5.

However, gas conditioning 14 is not required in all cases, so that this measure is optional.

3, only a high-temperature gasification reactor 4 is provided. The remaining reference numerals of Figure 1 have been retained unchanged. In the case of such high-temperature gasification, the return of flue gases after the induced draft fan 15 is only optional to the gas conditioning stage 14, this return line again being designated 16.

Hazardous waste, such as that generated in the chemical industry or in hospitals, can of course only be partially processed in medium-temperature gasifiers and will continue to be largely disposed of only using high-temperature gasifiers, especially at temperatures above 1400 ° C.

Claims (13)

1. Process for the thermal utilization of waste and / or waste fuels by gasification and subsequent combustion of the gases formed, characterized in that the waste and / or waste fuels are fed to a gasification reactor (3, 4) which is directly heated by gas and / or oil in that the gases withdrawn from the gasification reactor (3, 4) are fed to a combustion chamber (5) for energy, in particular steam generation, and that part of the flue gases from the combustion chamber (5) are returned to the gasification reactor (3) under pressure. 2. The method according to claim 1, characterized in that the temperature in the gasification reactor (3) is kept between 500 and 1200 ° C, preferably between 700 and 1200 ° C. 3. The method according to claim 1 or 2, characterized in that the gasification reactor (3, 4) loose fuel is compressed compressed via a feed screw. 4. The method according to claim 1, 2 or 3, characterized in that the gasification reactor (3, 4) lumpy fuels are supplied as bulk material. 5. The method according to any one of claims 1 to 4, characterized in that the gasification reactor (3, 4) is pressed into bales fuel is fed via an insertion device. 6. The method according to any one of claims 1 to 5, characterized in that the return of the flue gas under pressure in at least two zones of the gasification reactor (3) is carried out. 7. The method according to any one of claims 1 to 6, characterized in that the flue gases are used under the pressure of the induced draft fan (15) for pre-drying fuels for the carburetor (3). 8. The method according to any one of claims 1 to 7, characterized in that the flue gases are returned to the carburetor (3) for setting the reducing milieu and the CO₂ supply in the carburetor (3) via an adjustable throttle body. 9. The method according to any one of claims 1 to 8, characterized in that the flue gases for preheating the carburetor (3) are used when starting. 10. The method according to any one of claims 1 to 9, characterized in that the combustible gases drawn off from the carburetor (3, 4) are conducted via heat exchangers (19) of the boiler (6) of the steam generation. 11. The method according to any one of claims 1 to 10, characterized in that the flue gases are supplied to a gas conditioning stage (14) for preheating and / or adjusting the CO₂ supply and that the combustible gases from the gasifier (3, 4) via the gas conditioning stage (14) can be directed. 12. The method according to any one of claims 1 to 11, characterized in that a portion of the steam generated is returned to the gasification reactor (3, 4). 13. The method according to claim 12, characterized in that the vapor return to the carburetor (3, 4) is carried out together with the flue gases or the flue gases adjacent.

Images