EP0245295A1

EP0245295A1 - Use of waste material with a calorific value for cement production

Info

Publication number: EP0245295A1
Application number: EP86905716A
Authority: EP
Inventors: Albrecht Wolter; Wolfgang Grigel; Rolf Hartmann; Alexander Grisar
Original assignee: Dyckerhoff Engineering GmbH; Kloeckner Humboldt Deutz AG
Current assignee: Grisar Alexander; Kloeckner Humboldt Deutz AG
Priority date: 1985-09-21
Filing date: 1986-09-18
Publication date: 1987-11-19
Also published as: DE3533775C2; WO1987001692A2; WO1987001692A3; DE3533775A1

Abstract

Afin d'exploiter dans une plus grande mesure les possibilités offertes par la récupération de déchets pour la production de klinker, il est nécessaire d'homogénéiser les résidus solides de la carbonisation ou de la combustion partielle des déchets, avant leur adjonction au klinker de ciment et d'écluser une partie des gaz chauds de combustion chargés de matières toxiques. La quantité relativement élevée de déchets à pouvoir calorifique permet en outre des économies considérables d'énergie primaire lors de la production de klinker.In order to exploit to a greater extent the possibilities offered by waste recovery for the production of klinker, it is necessary to homogenize the solid residues from carbonization or partial combustion of the waste, before their addition to the cement klinker. and to lock out part of the hot combustion gases laden with toxic materials. The relatively high quantity of calorific waste also allows considerable savings of primary energy during the production of klinker.

Description

Utilization of waste materials containing calorific value in the manufacture of cement

The invention relates to a method for the recovery of calorific value-containing waste materials, in particular domestic and industrial waste, in connection with the heat treatment of fine-grained, mineral substances for the production of binders, in particular cement clinker, by preheating and calcining the raw meal in a preheater, firing in a rotary kiln and cooling the clinker with air, using heat from the heat treatment for pyrolysis of the waste materials in a smoldering furnace, the pyrolysis gases thereby incinerated in the preheater and the pyrolysis residues being introduced into the preheater or into the rotary kiln, and a device for carrying out the method.

From DE-OS 27 48 510 a method for recycling waste materials is known, in which the carbonization and / or incomplete combustion of the waste materials is combined with a burning process for the production of hydraulic binders, the pyrolysis gases being used in the burning process.

Since ballast-containing gas is passed through the clinker burning process in this process and therefore only very small amounts of pyrolysis gas can be used, DE 32 18 232 AI proposes that the waste materials be separated

ER _S ATZBLATT to dry, to carry out pyrolysis by indirect heating, and to burn the relatively low-ballast pyrolysis gas not in the rotary kiln but in the hottest area of the preheater, where a process temperature of approx. 850 ° C is required.

According to DE 33 20 670 AI, the above-mentioned process basond.ers is to become economical if the raw meal mixture is heated in a preheater upstream of the kiln, where all of the pyrolysis gases are burned from the smoldering furnace, and the smoldering furnace is heated exclusively with kiln exhaust gas and the solid pyrolysis residues are introduced into the furnace directly or indirectly via the lowest preheating stage.

If this process uses the preferred minerals containing carbon or hydrocarbons, in particular bituminous limestone or bituminous slate or bituminous marl, the process can be optimized relatively easily since the composition of these calorific value-containing starting materials fluctuates only relatively little. On the other hand, there are known to be very considerable fluctuations in the composition and calorific value of waste. Corresponding fluctuations in the chemical composition and the amount of pyrolysis residues occur. This means that only a very limited amount of waste can be used with this method if an even clinker quality is to be ensured.

The object of the invention is to modify a process for the preparation of binders, in particular cement clinker, in connection with the pyrolysis of waste materials, in particular domestic and industrial waste, so that a larger amount of the waste can be used without

REPLACEMENT LEAF the clinker quality is only impaired for a short time by excessive concentrations of unwanted components from the waste.

The object is achieved in that the pyrolysis residues are homogenized before being fed into the preheater or in the rotary kiln and some of the furnace gases are removed from the rotary kiln.

Pyrolysis is understood here to mean degassing, gasification and / or partial incineration of the waste in a smoldering furnace.

It is thereby advantageously achieved to incorporate more waste ash into the clinker without impairing the clinker quality, so that the usable amount of waste can be increased. This generally benefits the waste disposal, it saves landfill space. At the same time, clinker production is cheaper because a considerable part (more than 50% is possible) of the thermal energy required for clinker burning can be covered by recycling waste.

From cement production it is known (GB 20 43 853) that substances which disrupt the firing process, in particular those which tend to enrich the circulation, such as sulfides, chlorides, alkalis and / or heavy metals, by partial gas extraction (bypass) from the hot rotary kiln gases, as long as they have not yet condensed, to branch off. When introducing large quantities of waste into the system, such a partial gas extraction is very important, since otherwise blockages in the clinker burning process and / or loss in quality of the clinker can be expected.

The hot furnace gas discharged via the bypass is cooled and dedusted in a known manner. Such dusts can

REPLACEMENT LEAF at least partially added to the clinker again during grinding.

The heat required for the pyrolysis can be obtained either by introducing exhaust gas from the rotary kiln or by introducing hot air from the cooler into the smoldering furnace. By introducing air into the smoldering furnace there is a partial combustion and thus an additional heat transfer to the pyrolysis process. The amounts of OTeT.gas from the rotary kiln and the amounts of air from the cooler can be controlled depending on the desired pyrolysis temperature.

The proportion of flammable constituents of the pyrolysis residues depends on the pyrolysis temperature. If the pyrolysis is carried out at relatively low temperatures, the pyrolysis residue will still contain a considerable amount of combustible constituents, so that the utilization of these residues as fuel in the combustion zone of the rotary kiln has to be considered, especially if part of the combustion air passes through there Oxygen is replaced.

The combustion fume required for the combustion of the pyrolysis gas and, if necessary, the homogenized PyroXyser residue in the preheater, preferably in the calciner of the preheater, is obtained either directly from the clinker cooler through the rotary kiln or through a separate line (tertiary air line). The separate air duct is particularly advantageous because it allows both the rotary kiln and the bypass discharge to be made smaller. This variant is to be preferred in particular if the combustion in the rotary kiln takes place by partial supply of oxygen and / or if a part of the rotary kiln exhaust gases is otherwise used.

REPLACEMENT LEAF If coal dust is used for cement burning, the pyrolysis residues can be added to the coal grinding and homogenized and ground together with the coal.

In an advantageous variant of the method, the homogenized solid residues of the waste materials are given up in the hot area of the preheater, in particular in the calciner, especially if they contain relatively small amounts of combustibles. This means that a long distance is available for mixing into the clinker, which causes the clinker to become even more uniform.

If the pyrolysis residue is almost free of combustible components, it can be fed to the mill for the preparation of the raw cement meal.

In a particularly preferred process variant, the waste materials are pre-dried before pyrolysis. Such a measure is particularly indicated for the recycling of sludge, the water content of which is usually above 50%. The hot gas introduced into the preheater is then no longer "diluted" by the water ballast. With this process variant, large amounts of moist waste can be recycled without impairing the clinker quality and without additional fuel. The heat from the preheater is sufficient to pre-dry the waste materials. If the vapors of the drying that are not conducted in a closed circuit are directed into a part of the preheater that is at least 800 ° C., an unpleasant smell from the waste drying is avoided with certainty.

By subtracting the pyrolysis residues prior to their further use, it is also possible to free them from iron-containing components by magnetic separation and / or

REPLACEMENT LEAF for example, to screen large, disruptive components. A previous comminution can also be carried out to improve the homogenization effect.

The pyrolysis residues leaving the smoldering furnace are preferably cooled in a water bath and used for further use from there. For example, they can be homogenized in mixed beds or homogenization silos. Such devices are generally known. They are used in particular in the processing of raw cement material and also serve as a buffer store.

In an advantageous variant of the method, oxygen is used at least in part for the combustion in the rotary tube furnace instead of the air. As a result, the partial gas discharge can be kept narrow and the capacity of the preheater can be better used for the combustion of the pyrolysis gases. Furthermore, the use of oxygen allows the use of inferior fuels, especially pyrolysis residues.

A relief of the preheater can also be achieved in that the exhaust gas from the rotary kiln is not passed into the preheater, but is otherwise used for energy, for example for generating district heating or electricity.

For system relief of elements or compounds that are already volatilized in the temperature range of the preheater, such as highly volatile heavy metals or heavy metal compounds that arise during pyrolysis or during the combustion of pyrolysis residues and cycles

SPARE2BLADE form, some of the exhaust gases from the preheater can also be discharged and, for example together with the bypass gas from the rotary kiln, cooled and dedusted.

A device for carrying out the method according to the invention consists of two parts of the system, a clinker burning system, consisting of preheater, if possible with calciner, rotary kiln and clinker cooler and a smoldering furnace, in which the waste is fed and where it is charred and / or partially burned when heat is transferred from the kinker burning system. is pyrolyzed), with devices for homogenizing the pyrolysis residues after charring and / or partial incineration of the waste and a line for the partial removal of hot rotary kiln gases. A homogenizer consists of at least one silo or a stockpile with a mixing device, as well as a control proportional to the quantity of raw meal. As a result, the greatest possible amount of waste can be used without exceeding the maximum concentrations of pollutants in the clinker. The partial gas discharge is preferably located at the inlet of the rotary kiln. At the temperatures prevailing there, most of the interfering substances are in the gas phase.

In an advantageous embodiment, the smoldering furnace is designed as a rotary tube furnace. The waste materials can be well aerated and pre-homogenization also occurs.

The invention is further explained below using an exemplary embodiment shown in the block diagram. The diagram shows only the directions of the gas and solid flows, but no valves, acceleration, control and regulating elements.

REPLACEMENT LEAF The clinker combustion system consists of a preheater 1 (here formed from four heat exchanger cyclones 2 with the calciner 3), a rotary kiln 4 and an air cooler 5, here designed as a grate cooler. Raw meal 6 is fed into the upper area of the preheater 1, the clinker at 7 is removed from the cooler 5.

In this example, heating value-containing waste 8 is vorgetxTjckπet via the dryer 9 heated with waste heat from the preheater 1 before it reaches the smoldering furnace 11 via the line 10. Without waste recycling, the gases from the rotary kiln 4 pass via the line 12 directly into the calciner 3, into which fuel and hot air from the cooler are also conducted. In the method according to the invention, at least some of the rotary kiln exhaust gases are passed via 13 and / or some of the cooler exhaust air via 17 into the smoldering furnace 11; there is a pyrolysis and a separation of the waste into combustible pyrolysis gases 14 and solid pyrolysis residues 15, which as a rule also contain components containing calorific value.

The pyrolysis residues from the smoldering furnace 11 are cooled in a water bath 19 and then subjected to magnetic separation and / or sieving, or, if appropriate, comminution in the conditioning stage 20 before they are fed to the homogenization 18. Magnetic components and unwanted oversize particles are removed at 25.

How the residues are most advantageously processed depends on the thermal treatment of the waste in the smoldering furnace. With a pure smoldering due to the furnace gases 13, which hardly contain any oxygen, the residue can still contain so much combustible that

REPLACEMENT LEAF it is discharged at 30, for example, and is given to the rotary kiln 4 together with high-quality fuel, for example coal dust, via the burner 21.

In the case of partial incineration of the waste in particular, it makes sense to enter the homogeneous, solid, predominantly mineral residues via line 22 directly into the hot area of the preheater or the calciner of the preheater or into the inlet shaft of the rotary kiln. There is a long way through the lower heat exchanger cyclone 23, the feed line 24 and the entire rotary kiln 4, so that the pyrolysis residue is mixed very uniformly with the raw meal and installed in the clinker.

There is also the possibility of subtracting the homogenized residues above 30 and metering them in during coal grinding or kink grinding,

A portion of the hot furnace exhaust gases can be removed via line 26, which results in a dilution of the substances in the circuit which are undesirable for the clinker production and condense again on cooling of the raw meal. When recycling large quantities of waste, greater attention must be paid to interrupting or reducing such a cycle. The further treatment of the gas drawn off at 26 - essentially cooling and dedusting - is no longer shown. Depending on the type of pollutants, these dusts can be added to the clinker again during grinding in certain quantities.

Part of the combustion air 31 for the rotary kiln 4 can be replaced by oxygen 32.

REPLACEMENT LEAF According to this procedure, half a kilogram of household waste per 1 kg of clinker can be disposed of. The amount of high-quality fuel for the production of 1 kilogram of clinker should be able to be reduced to 300 kcal, because the hot gas from the smoldering furnace can be sufficient to cover the heating requirements of the preheater, and the pyrolysis residues can at least partly be used in the flame zone of the rotary kiln .-.

The exhaust gases 27 of the preheater 1 are sufficient for predrying the waste materials 8 in the dryer 9. The vapors 28 of the drying, which are not circulated, are introduced into the preheater 1 where there is still at least 800 ° C. This destroys all odorous substances from the drying of waste.

The process according to the invention does not require any significant modification and expansion of conventional plants for the production of binders, since the additional gases from waste recycling are not ballast but fuel.

In the block diagram, the smoldering furnace 11 is shown as a rotary drum operated in the Gjageπstrom. However, it is also possible to use a ^* DC drum or another type of oven.

REPLACEMENT LEAF

Claims

1.Process for recycling waste materials containing calorific value, in particular domestic and industrial waste, in connection with the heat treatment of fine-grained, mineral substances for the production of binders, in particular cement clinker, by preheating and calcining the raw meal in a preheater, burning in a rotary kiln and cooling of the clinker with air, heat from the heat treatment being used for pyrolysis of the waste materials in a smolder, the pyrolysis gases thereby incinerated in the preheater and the pyrolysis residues being introduced into the preheater or into the rotary kiln, characterized in that the pyrolysis residues are input before are homogenized in the preheater or in the rotary kiln, and a portion of the kiln gases from ^* is discharged to the rotary kiln.

2. The method according to claim 1, characterized in that for the pyrolysis of the waste hot exhaust air from the clinker cooling is passed into the smoldering furnace.

3. The method according to claim 1, characterized in that furnace gases are passed from the rotary kiln into the smoldering furnace for the pyrolysis of the waste materials.

4. The method according to any one of claims 1 to 3, characterized in that the homogenized pyrolysis residues are abandoned in the flame zone of the rotary kiln.

εRSA _T Z _L ATT

5. The method according to any one of claims 1 to 3, characterized in that the homogenized pyrolysis residues in the hot area of the preheater, in particular in the calciner, are abandoned.

6. The method according to any one of claims 1 to 5, characterized in that the waste materials are pre-dried before pyrolysis.

7. The method according to claim 6, characterized in that exhaust gas from the preheater is used for predrying the waste materials.

8. The method according to claim 6 or 7, characterized in that the vapors of the drying are passed into an at least 800 ° C hot part of the preheater.

9. The method according to any one of claims 1 to 8, characterized in that the pyrolysis residues are crushed before the homogenization.

10. The method according to any one of claims 1 to 9, characterized in that the pyrolysis residues are subjected to magnetic deposition prior to homogenization.

11. The method according to any one of claims 1 to 10, characterized in that coarse constituents of the pyrolysis residues are sieved off before homogenization.

12. The method according to any one of claims 1 to 11, characterized in that oxygen is used at least in part for the combustion in the rotary kiln instead of air.

REPLACEMENT _B LATT

13. An apparatus for performing the method according to any one of claims 1 to 12, consisting of a plant for clinker burning with preheater, rotary kiln and clinker cooler and a smoldering furnace for pyrolysis of waste materials, with devices for transferring heat from the clinker burning process to the waste materials in the smoldering furnace and for introducing pyrolysis gases from the smoldering furnace into the preheater, in particular into the calciner of the preheater, and of pyrolysis residues from the smoldering furnace into the preheater or rotary tube furnace, characterized in that devices for homogenizing (18, 20) the pyrolysis residues and a line (26 ) for the partial removal of hot furnace gases from the rotary kiln (4).

14. The apparatus according to claim 13, characterized in that the smoldering furnace (11) is designed as a rotary kiln.

REPLACEMENT LEAF