EP0588075B1 - Combustion process and furnace for burning waste - Google Patents

Abstract

A method and a combustion furnace are provided by means of which waste which is predominantly of organic nature can be burnt effectively and uniformly. The combustion furnace comprises two bottlenecks, one above the other, constituted by rocking grates. The upper rocking grate essentially serves to subject the solids to pre-combustion, namely to drying, degasifying, and partial gasifying, and to supply the material uniformly in doses to the fire bed which is located on the lower grate and in which complete gasification takes place. Rotational movements of both grates provide for uniform passage of the material through the shaft without the risk of burn-through occurring along the edges so that the entire combustion process becomes highly uniform.

Description

The invention relates to a method and a combustion furnace for burning lumpy organic solids, preferably waste, and for generating fuel gases according to the preamble of claim 1 and claim 4. Such a method and such a combustion furnace are from DE-PS 26 04 409 and DE-OS 27 35 139 known.

The known methods and the known incinerators are used to incinerate solid wastes of different consistency as environmentally friendly as possible, which is actually possible because essentially only ash and harmless exhaust gases are produced as combustion products. The object of the present invention is now to further improve this known method and this known incinerator so that proper combustion is ensured even with a larger waste throughput and thus an enlarged shaft cross-section, with a compact and comparatively constructive design simple design of the incinerator, and that the resulting fuel gases are suitable for energy generation due to their properties and the constancy of their composition. In terms of the method, this object is achieved by the features of patent claim 1 and in terms of the device by the features of patent claim 4.

According to the invention, two successive bottlenecks are therefore provided in the shaft, these bottlenecks in practice being expediently formed by tilting gratings. The upper grate serves to stow the waste introduced into the shaft from above and to feed the shaft space between the two grates in a metered manner. The waste is dried and degassed above the upper grate, in some cases already gasified due to the reaction gases supplied in the area of the upper grate. The waste, which is dried, degassed and already partially gasified, enters the space between the two grates and is then stowed through the lower grate, and with the addition of reaction gas, the waste is completely gasified to ashes and fuel gas, the ashes passing through the grate falls down and the fuel gases are also drawn off downwards. The two grates are expediently excited to vibrations in the form of continuous or intermittent periodic rotary movements of limited amplitude, which ensures that the jammed pieces of slippage slide smoothly and prevents burns through and / or burns up in the waste stack.

Further advantages of the invention result from the following description of an exemplary embodiment of an incinerator according to the invention and from the associated drawing. The only figure shows a vertical section through the incinerator.

In the drawing, the incinerator is generally designated 10. An upright shaft 11 is arranged in the furnace, into which a tube 12 opens from above for filling the waste to be incinerated. Two narrow points are provided in the shaft 11, which are formed by grids 13 and 14. The grate 13 is a tilting grate which can be pivoted about a central axis 13a, the grate passage having the form of a gap 15a which is delimited on the one hand by the inner wall of the shaft 11 and on the other hand by the outer edge of the grate 13. The axis 13a is designed as a hollow shaft, the interior of which serves as a feed line for reaction gas, which then passes through outlet openings 13b of the grate 13 into the interior of the shaft 11. The basic structure of such a tilting grate 13 is known, so that further detailed explanations can be dispensed with here. In addition, reaction gas can be supplied through the lines 13c and 14c running in the shaft wall and opening into the shaft interior. However, it should be pointed out that in many cases the reaction gas feeds 13b, 14b or 13c, 14c can be used, in the latter case the grate shafts 13a, 14a can be dispensed with as hollow shafts. The grate 14 forming the lower end of the shaft 11 has a similar structure, which can be pivoted about its axis 14a, which is also designed as a hollow shaft and feeds reaction gas to the outlet openings 14b. Below the grate 14 there is an ash chamber 16 with an ash box or container 17 only indicated in the drawing. Finally, the shaft 11 has an inlet opening 22 close to its ceiling, through which drying and / or reaction gas can be introduced if necessary.

Below the lower tipping grate 14 there is an exhaust pipe 18 from the shaft 11 or the ash chamber 16, which ends with its nozzle end 18a in a mixing chamber 19, which is provided on its inner wall with inlet nozzles 20 for reaction gas and which is only partially shown in a combustion chamber 21 opens. The mentioned inlet nozzles 20 are arranged and adjusted so that an intensive mixing of smoldering and Reaction gas takes place.

The incinerator 10 shown operates as follows. To start the combustion process, the substances to be burned are first fed to the shaft 11 via the pipe 12, the substances accumulating over the grate 13. It thus forms on the grate 13 the fabric stack indicated in the drawing with the upper cone of bulk. Now the reaction gas supply to the two grates 13 and 14 and / or the openings 13c, 14c is opened and the waste stack above the grate 13 is ignited by a known igniter, not shown, directly above the grate surface or the passage gap 15. After a certain amount Starting phase forms a bed of embers on the grate 13. The waste in the uppermost region of the material stack undergoes drying, specifically through the temperature that is formed, optionally supported by the drying and / or reaction gas flowing in from the opening 22. The pieces of material located in the middle region between the drying zone and the ember bed of the stack of materials are degassed due to the temperature transferred from the ember bed mentioned, and the pieces of waste located in the lower region of the waste stack, which are located in the ember bed or directly above it and in the flow of that emerging from the outlet openings 13b Reaction gas are at least partially subjected to a gasification process. The beginning of the gasification process with the beginning of a dissolution of the carbon structure leads to a dismantling of the waste pieces so that they pass through the passage gap 15a, whereby a new stowage takes place through the grate 14, the passage gap 15b of which can be dimensioned smaller than the passage gap 15a of the grate 13. In this fill on the grate 14 from partially or pre-gasified waste, the reaction gases supplied from the grate 14 via the openings 14b and / or the mentioned lateral shaft wall openings 13c, 14c now lead to the formation of an ember bed with temperatures that lead to a complete gasification of the substances leads to ash and fuel gas. The ash passes through the narrow passage gap 15b and falls into the ash chamber 16, the fuel gases, namely all the fuel gases generated in the shaft 11 are drawn off downwards and discharged from the shaft via the line 18. The fuel gases then pass through the nozzle 18a into the mixing chamber 19, where they are mixed intensively with reaction gas supplied through the nozzles 20; the fuel gas / reaction gas mixture entering the combustion chamber 21 from the mixing chamber 19 is then burned in the combustion chamber 21.

Air can also be used as the reaction gas supplied through the openings 13b, 14b, 13c, 14c, 22 and the nozzles 20, but also flue gas mixed with air or with oxygen and removed from the system, or even flue gas alone at a very high ember bed temperature. A reaction gas consisting of flue gas or carbon dioxide and - instead of air - pure oxygen is particularly effective because it does not contain nitrogen. The nitrogen in the air does not promote combustion, but often leads to the formation of undesirable nitrogen oxides. The temperatures in the area immediately above the upper grate 13 can be, for example, approximately 600 ° C. to 800 ° C., those in the area directly above the lower grate 14, for example, up to 900 ° C., the temperature of both stages being controllable via the reaction gas supply .

The two gratings 13 and 14 are preferably excited to tilt movements via their axes 13a, 14a. The upper grate 13 introduces a mechanical pushing movement into the material, with the result that even with larger shaft cross-sections there are no central dead spaces in the waste stack and no burn-through phenomena in the outer region of the stack. The rotational movements of the lower grate 14 ensure that the formation of fine-grained ashes and the transport of the ashes through the grate gap is promoted. The upper grate 13 is expediently excited to rotate at a higher frequency and / or amplitude than the lower grate 14.

A major advantage of the invention is that the drying, degassing and gasification process is very even and runs without significant peaks and can be accelerated if necessary, which considerably improves both the performance and the constancy of the gas composition. The latter is of particular importance when the fuel gases are to be used to operate a gas engine, that is, the combustion chamber 21 is the combustion chamber of a gas engine. However, even if the gases extracted from the shaft are only burned for the purpose of implementation, are only partially used in the system to maintain the shaft temperature and / or as a reaction gas, or are used to operate heat exchangers, a uniform combustion process has proven to be beneficial. Furthermore, it has been shown that the intensive material movement, caused by the moving grates, and the large-area reaction gas supply means that the material can be brought into a very strong reaction, with the result of an increase in performance compared to previous incinerators. It is also possible to equip the incinerator only with the reaction gas feeds 13b, 14b or only with the reaction gas openings 13c, 14c; the decision depends in particular on the size of the incinerator and the throughput and nature of the waste materials. Gas will then be supplied through the upper inlet opening 22 if the waste is very moist (drying gas supply) or if an ember bed reaching into the upper shaft area is desired (reaction gas supply). Finally, it is advantageous that it is not necessary in the invention to provide central nozzle pipes and / or agitators in the shaft. In addition, the arrival and departure times are reduced due to the lower use of materials. Finally, it should also be mentioned that solids are also understood to mean pasty substances and solids mixed with liquids, such as waste oil.

Claims (6)

1. Method of burning of particulate organic solids, preferately waste materials, and of producing combustible gases, with which the solid materials are accumulated above a first narrows (15b) provided between a shaft (11) in which the waste materials are received, and a combustion chamber (21) provided downstream the shaft and are dried by heating, degasified and gasified while reaction gas is added and with which the resulting combustible gases are withdrawn through the narrows (15b) downwardly and are subsequently burned while air is added, characterized in that the solids are preaccumulated, dried, degasified and partly gasified above a further narrows (15a) provided in the shaft spaced above the first narrows (15b) and are then passed for complete gasification through the further narrows (15a) to the shaft space between the two narrows.
2. Method according to claim 1, characterized in that the solids are subjected in the range of each narrows to mechanical rocking vibrations, and especially are subjected in the range of the further narrows to rocking vibrations of higher frequency and amplitude in comparison to that in the range of the narrows being arranged below.
3. Method according to claim 1 or 2, characterized in that as a reaction gas air, flue gas obtained from the system or flue gas mixed with air or pure oxygen or carbon dioxyde is used.
4. A combusion furnace for performing the method according to one of the claims 1 to 3 with an upright shaft (11) to receive the solids, a grate (14) located at the lower end of the shaft and forming a narrows, reaction gas supply lines opening into the shaft (11) and with a combustion chamber (21) directly below or laterally below the grate (14), characterized in that a further grate (13) forming a further narrows is arranged above the grate (14) in a spaced manner and in that the discharge openings of the reaction gas supply lines (13b, 14b, 13c, 14c, 22) open into the shaft ranges of both grates (13, 14) or are directed onto these ranges.
5. The combustion furnace according to claim 4, characterized in that both of the grates (13, 14) are formed as closed roof-type grates, which are to be powerdriven with different frequency and different amplitude.
6. The combustion furnace according to claim 4 or 5, characterized in that upstream the combustion chamber (21) a mixing chamber (19) is arranged into which the combustible gases are fed by means of a nozzle (18a) and which is provided with reaction gas inlet nozzles (20).

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