BE1029040B1 - Process for operating a plant for the production and/or handling of cement clinker - Google Patents

Abstract

The present invention relates to a method for operating a plant (10, 11) for producing and/or handling cement, comprising the steps: - removing a material sample (42) of cement clinker from a plant (10, 11) for producing and/or handling of cement, - dosing an activating fluid to the material sample (42), - determining the gas pressure and/or the amount of hydrogen gas and/or the amount of elemental aluminum in the mixture of the activating fluid and the material sample (42), and - controlling/ Regulating the fuel discharge (36, 38) from a fuel store (18, 34) for feeding into a firing device (12, 14) of the plant (10, 11) for the production of cement depending on the gas pressure determined and/or the quantity of hydrogen gas determined and / or elemental aluminum or - controlling / regulating the cement discharge (54) from a cement store (56, 58) for feeding into a handling device (52) of the system (10, 11) for handling ation of cement as a function of the determined gas pressure and/or the determined amount of hydrogen gas and/or elemental aluminum.

Description

' BE2021/5041 Method for operating a plant for the production and/or handling of cement clinker The invention relates to a method for operating a plant for the production and/or handling of cement clinker. The invention also relates to a plant for the production and/or handling of cement from cement clinker, sulphate carrier and additives. The method and the plant are used in particular for the production of cement clinker and cement for use as aerated concrete and concrete with air voids.

Aerated concrete and those with an increased proportion of air voids are usually used for the production of bricks or prefabricated components or precast concrete and are characterized by a lower density compared to standard concrete without pore formers due to an additional desired increased number of pores or an increased volume of the pores or both. The relatively large pores and the additional pores have a positive influence on the workability, frost resistance, segregation, durability against sulphate-rich solutions and prevent, for example, shrinkage or cracking in the concrete.

Cement for use as aerated concrete or a concrete with an increased proportion of air voids is usually produced by metering aluminum powder into the cement during grinding or the production of a concrete. The aluminum powder forms hydrogen gas with water in an alkaline environment, especially during the hydration of cement. The hydrogen gas forms the pores in the finished building material.

However, if the elemental aluminum content in the clinker or cement is too high, the formation of hydrogen gas can lead to an undesirable increase in volume. This increase in volume is particularly disadvantageous for the shaping of cast concrete components and precast concrete parts.

A method for producing a cement is known from DE 102014 113 548 A1. In the cement clinker production process, non-resorbed elementary aluminum remains in the finished cement clinker, particularly when large amounts of secondary fuels are used during the clinker phase formation. For example, residues from composite packaging made from secondary fuels that are not oxidized in the kiln process and are incorporated into the clinker mineralogy serve as a source of elemental aluminum in the cement clinker. In addition to the always present proportions of oxidic aluminum in the cement clinker, the elemental aluminum content cannot be quantified using the usual X-ray methods (XRF, XRD). Proceeding from this, it is the object of the present invention to provide a method for operating a plant for the production and/or handling of cement and cement clinker, wherein a cement clinker can be produced which is suitable for use as aerated concrete or suitable as concrete rich in air voids without the shaping of the concrete components to be adversely affected by an undesirable increase in volume.

According to the invention, this object is achieved by a device having the features of independent method claim 1 and by a method having the features of independent device claim 10 . Advantageous developments result from the dependent claims and the description.

According to a first aspect, a method for operating a plant for the production and/or handling of cement comprises the steps: - taking a material sample of cement from a plant for the production and/or handling of cement, - a preferably over-stoichiometric dosing of an activating fluid to the material sample , - Determining the gas pressure and/or the amount of hydrogen gas and/or the amount of elemental aluminum in the mixture of the activating fluid and the material sample - Controlling/regulating the fuel discharge from a fuel store for feeding into a furnace of the plant for the production of cement in Dependence of the determined gas pressure and / or the determined amount of hydrogen gas and / or elemental aluminum or

- Controlling/regulating the cement discharge from a cement store for feeding into a handling device of the plant for handling cement depending on the determined gas pressure and/or the determined amount of hydrogen gas and/or elemental aluminum.

The term cement preferably also includes cement clinker and/or a mixture of cement clinker and cement additives, such as sulphate carriers or composite material, in particular limestone, fly ash, blast furnace slag. A plant for the production of cement is a plant for the production of Portland cement clinker or a plant for the production of clinker clinker compositions that differ, for example clinker based on calcium sulfoaluminate, or a plant for the production of a burned precursor for binders from mixtures of burnt lime and pozzolan. Furthermore, the process can be used in plants without their own clinker production for the production of cement from delivered clinker, sulphate carrier and additives. A handling device is to be understood, for example, as a crushing device for grinding or crushing the cement, in particular the cement clinker, or a mixing plant for mixing a cement from cement clinker and additives or different cements. A plant for the production of cement preferably comprises a preheater into which raw cement meal is fed and preheated in countercurrent with hot gases. In particular, the preheater has a plurality of cyclone stages, with the cyclones serving to separate solids from the gas stream. A calciner for precalcining the raw meal is arranged between the last and penultimate cyclone stage in the flow direction of the raw meal. The calciner has a calciner furnace to which, for example, a secondary fuel such as waste is fed. The preheated raw cement meal leaving the preheater is fed to a kiln, in particular a rotary kiln, and burned therein to form cement clinker. The heat in the furnace is preferably supplied via a burner that can be operated with a wide variety of so-called standard fuels (e.g. gas, coal, oil) and/or so-called secondary fuels (e.g. waste, solvents, municipal waste). In particular, waste and municipal waste also contain significant amounts of elemental aluminum, for example from composite packaging.

The kiln exhaust gas formed during combustion is at least partially introduced into the preheater and flows through it in countercurrent to the raw meal to be preheated. Following the kiln, the banned cement clinker is cooled in a clinker cooler and optionally crushed.

A plant for handling cement includes, for example, a handling device, in particular a mixing store, preferably a cement store, or a comminution device, such as a grinding plant or a crushing plant, to which the cement, in particular the cement clinker, is fed for comminution. Such a plant can, for example, be part of a cement production plant described above. Sampling to take a sample or a manually drawn sample can take place, for example, at the kiln outlet, the clinker cooler or from the transport routes for cement, in particular cement clinker from the kiln to the clinker store or to a cement store. Furthermore, the process can be used in plants without their own clinker production for the production of cement from delivered clinker, sulphate carrier and additives. The preferably comminuted material sample is removed, for example, from the handling device or the cooler of a plant for the production of cement and introduced into a sample container. The sample container can preferably be closed. The activation fluid is preferably metered into the sample container in sufficient quantity, preferably over-stoichiometrically, by means of a metering device. Deviating from this, the dosing can also be done by adding alkali metal hydroxide powder or tablets with water separately. The sample is homogenized, for example, by vibration or shaking before or after the addition of the activating fluid. The gas pressure inside the sample container is then determined. The pressure measurement or the determination of the hydrogen gas preferably takes place continuously from the point at which the activating fluid is added to the container. During the pressure or hydrogen gas determination, the sample container is preferably closed and the detector is connected to the sample container volume directly or via a connection such as a hose. In the well-known and frequently used in the cement industry chemical analytical methods based on

X-rays cannot distinguish between oxide aluminum, which is a major component in clinker, and incompletely oxidized elemental aluminum. The gas pressure is preferably determined using a pressure measuring probe or other known measuring devices for determining the gas pressure. The amount of hydrogen gas is preferably determined by measuring the volume flow or other known measuring devices for determining the amount of gas.

Control/regulation of the fuel discharge or the cement discharge depending on the determined gas pressure and/or the determined amount of hydrogen gas and/or elemental aluminum made it possible to easily and relatively quickly adapt the fuel discharge or the cement discharge to the requirements placed on the end product with regard to air entrainment. Such a method ensures that the intermediate product or the end product has a content of elemental aluminum that can be used for aerated concrete or for the production of concrete rich in air voids, but at the same time does not negatively influence the shaping of the components through an uncontrolled increase in volume.

According to a first embodiment, the activating fluid is an alkali metal hydroxide solution, for example potassium hydroxide solution and/or sodium hydroxide solution or an alkaline solution. The activation fluid reacts with the sample material to form, among other things, hydrogen gas. A reaction equation of the reaction of the cement clinker or the pre-calcined raw material of the sample material with the activating fluid is as follows: Al + KOH + 3 H20 = 1 K[AI(OH)4] + 1.5 H2 (1) The use of an alkali hydroxide solution or an alkali enables the determination of the amount of hydrogen gas produced in the above reaction, which can be used to draw conclusions about the proportion of elemental aluminum in the sample.

According to a further embodiment, the amount of elementary aluminum in the material sample is calculated from the determined amount of hydrogen gas. The proportion of elementary aluminum is preferably to be calculated via a linear relationship to the determined amount of hydrogen gas. Preferably 1.5 moles of hydrogen gas are formed per mole of elemental aluminum. A possible arithmetic operation for calculating the proportion of aluminum in the sample is as follows: Al [g] = (H2 [1] / 33.6 [I]) * 26.9815 [g] The arithmetic operation for quantifying the elementary aluminum can be carried out directly in a processor at the analysis device or after transmission of the raw data in a computer system directly connected to the detector.

According to a further embodiment, the amount of elemental aluminum in the fuel discharge or in the cement discharge is controlled/regulated. The fuel discharge is preferably formed from a mixture of different fuels, each of which has a known proportion of aluminum. During control/regulation, the proportion of the different fuels used to form the fuel discharge is preferably varied so that the amount of elemental aluminum in the fuel discharge is increased or reduced, preferably with the aim of adding a cement, in particular a cement clinker, with a desired elemental aluminum content generate. The situation is similar with the control/regulation of the cement discharge. The cement output is preferably formed from a mixture of different cements, in particular cement clinker and/or clinker additives, each of which has a known proportion of aluminum. During control/regulation, the proportion of the different cements used to form the cement discharge is preferably varied, so that the amount of elemental aluminum in the cement is increased or reduced, preferably with the aim of producing a cement with a desired elemental aluminum content.

According to a further embodiment, the gas pressure determined after preferably super-stoichiometric addition of the activating agent, the amount of hydrogen and/or the amount of the content of elemental aluminum preferably determined therewith is compared with a respective limit value and, if there is a deviation in the determined gas pressure, the amount of hydrogen gas and / or the amount of elemental aluminum from the limit increases or decreases the amount of elemental aluminum in the fuel discharge or the cement discharge. The contributions of different fuels can be adjusted in such a way that a target value is maintained, or a device for feeding elementary aluminum into the cement clinker production process, for example, can be controlled in a targeted manner. A predetermined limit value is preferably stored in each case for the gas pressure, the amount of hydrogen gas and/or the amount of elementary aluminum, in particular in the analysis device.

For example, the amount of elemental aluminum in the fuel exhaust is increased when the gas pressure falls below the gas pressure limit. The amount of elemental aluminum of the fuel effluent is preferably increased when the amount of hydrogen gas or the amount of elemental aluminum falls below the corresponding limit. For example, the amount of elemental aluminum of the fuel exhaust is reduced when the gas pressure exceeds the gas pressure limit. The amount of aluminum element of the fuel effluent is preferably reduced when the amount of hydrogen gas or the amount of aluminum element exceeds the respective limit.

In a further embodiment, the levels of elemental aluminum in individual fuels are not clearly known. In this case, a so-called adaptive mixture control can also be used. With each measurement, an actual state is first recorded. This actual state can be used to trigger control of a target state for the subsequent analysis based on a known estimate of the elemental aluminum content in the known fuels. The follow-up analysis determines a deviation between the expected change in elemental aluminum levels based on the previous estimate of elemental aluminum levels in the fuels or cements and the actual change in elemental aluminum levels achieved. From the difference between the expected change in elemental aluminum and the new actual value for elemental aluminum in the subsequent analysis, a new, improved estimate of the elemental aluminum content can be derived for each of the fuels or cements involved in the control. The following control interventions are processed with this new, improved estimation until an improved, generally more up-to-date estimation is available. According to a further embodiment, the material sample is taken from a preheater and/or a cooler of the plant for the production of cement clinker. It is also conceivable that the material sample is taken from or after a handling device of a plant for handling cement clinker.

According to a further embodiment, the amount of hydrogen gas in the material sample is determined continuously until no further increase in the gas pressure or the hydrogen gas concentration is observed or over a period of about 2 to 240 minutes, preferably 2 to 45 minutes, most preferably 45 to 240 minutes, in particular more determined to be 240 minutes. If only a slight increase in the gas pressure or the hydrogen concentration is observed over time during the measurement, the measurement can also be aborted and the last result used as the measured value. The measurement should preferably take place over 2-45 minutes and can be extended to 45-240 minutes or extended beyond 240 minutes, for example, if incomplete conversion is suspected, for example due to a coarse particle size distribution. This enables a relatively quick control/regulation of the fuel discharge or the cement discharge in the ongoing cement production process.

According to a further embodiment, the fuel discharge is produced from a plurality of fuels with different proportions of elemental aluminum. The cement discharge is preferably made from a plurality of cements with different proportions of elemental aluminum.

The invention also includes a plant for the production and/or handling of cement. The plant preferably comprises at least one fuel store or cement store with an outlet for discharging a fuel discharge from the fuel store or a cement discharge from the cement store. The plant also has a firing device which is connected to the fuel store for supplying the fuel discharge and/or a handling device which is connected to the cement store for supplying the cement discharge. The system also includes an analysis device for analyzing a material sample, which is connected to the outlet of the fuel store or the cement store in such a way that it controls/regulates the fuel discharge from the fuel store or the cement discharge from the cement store. The analysis device is designed in such a way that it determines the amount of hydrogen gas and/or the gas pressure in the material sample and controls/regulates the fuel discharge or the cement discharge depending on the determined quantity of hydrogen gas and/or the determined gas pressure.

The embodiments and advantages described with reference to the method also apply to the plant for the production and/or handling of cement clinker in accordance with the device.

The analysis device is preferably designed in such a way that it determines the quantity of hydrogen gas and/or the gas pressure in the material sample and controls/regulates the fuel discharge or the cement discharge depending on the determined quantity of hydrogen gas and/or the determined gas pressure.

The analysis device preferably includes a dosing unit for preferably over-stoichiometric dosing of the activating fluid into the material sample 42, in particular the sample container. The analysis device comprises in particular a pressure sensor for determining the gas pressure in the sample material, in particular the gas pressure inside the sample container. The analysis device also comprises, or alternatively, a detector for detecting hydrogen gas, in particular for determining the amount of hydrogen gas contained in the material sample.

According to one embodiment, the analysis device is designed in such a way that it calculates the amount of elemental aluminum in the sample material from the determined amount of hydrogen gas.

According to a further embodiment, the analysis device is designed in such a way that it controls/regulates the quantity of elemental aluminum in the fuel discharge as a function of the determined quantity of hydrogen gas and/or the determined gas pressure.

According to a further embodiment, the fuel store comprises a plurality of fuels which are arranged in separate areas or stores within the fuel store. The fuels can preferably be removed separately from the fuel store, so that the fuel discharge can be formed from a predetermined quantity of different fuels. Preferably, the cement bed comprises a plurality of cements arranged in separate areas or beds within the cement bed. The cements can preferably be removed separately from the cement store, so that the cement discharge can be formed from a predetermined quantity of different cements.

DESCRIPTION OF THE DRAWINGS The invention is explained in more detail below using several exemplary embodiments with reference to the attached figures. 1 shows a schematic representation of a section of a plant for the production of cement clinker according to an exemplary embodiment.

FIG. 2 shows a schematic representation of a section of a plant for handling cement clinker according to a further exemplary embodiment. Fig. 1 shows a section of a plant 10 for the production of cement clinker. For the sake of simplicity, FIG. 1 shows only a calciner 12 , a furnace 14 and a cooler 16 connected to the rotary kiln 14 . The plant 10 for the production of cement clinker preferably has a preheater for preheating raw meal. The preheater comprises, for example, a plurality of cyclones arranged in stages relative to one another for separating solids from the solids/gas mixture flowing through the preheater. The calciner 12 is preferably arranged between the penultimate and the last cyclone stage of the preheater and is used for calcining the preheated raw meal. The calciner 12 has, in particular, a calciner firing system to which a first fuel 22 - 26 from a first fuel store 18 is supplied. The oven 14, in particular a rotary kiln, is connected to the preheater in the flow direction of the raw meal. The preheated raw meal is burned into cement clinker in the rotary kiln 14 . The furnace 14 has a furnace furnace 20 to which a second fuel 28-32 from a second fuel store 34 is supplied. The medicinal gas emerging from the oven 14 is fed into the preheater and flows through it in countercurrent to the raw meal to be preheated.

The kiln 14 is followed by a cooler 16 for cooling the burned cement clinker. The cooler 16 is, for example, a grate cooler in which the raw meal is cooled in a cross-flow and is conveyed in the conveying direction.

For example, the calciner 12 is connected to the first fuel store 18 and the furnace 14 to the second fuel store 34, so that the fuel 22-26 from the first fuel store 18 is supplied to the calciner 12 and the fuel 28-32 from the second fuel store 34 is supplied to the furnace 14 . It is also conceivable that the plant has only one fuel store that is connected both to the calciner 12 and to the furnace 14 for charging with fuel. Each fuel store 18, 34 preferably has a plurality of fuels 22-32 which have different properties, in particular compositions, in particular also different compositions and amounts of the respective incombustible residues, the so-called fuel ashes. The fuels 22-32 are preferably stored in different areas of the respective fuel store 18, 34 or in separate stores, so that a targeted withdrawal of a desired fuel 22-32 from the fuel store 18, 34 is possible.

For example, each of the fuel stores 18, 34 has at least three different fuels 22-32. The first fuel store 18 has, for example, a fuel 22 which has an increased proportion of elemental aluminum relative to the other fuels 24 , 26 . Furthermore, the first fuel store 18 has, for example, a fuel 24 which has a lower proportion of elemental aluminum relative to the other fuels 22 , 26 . The first fuel store 18 also has, for example, a fuel 26 that is a standard fuel and preferably has a proportion of elemental aluminum that is lower than that of the fuel 22 with an increased proportion of elemental aluminum and higher than the fuel 24 with a lower proportion of elemental aluminum is. The first fuel discharge 36 discharged from the first fuel store 18 is a mixture of the fuels 22, 24, 26 of the first fuel store 18. The second fuel store 34 has, for example, a fuel 28 which has an increased proportion relative to the other fuels 30, 32 has elemental aluminum. Furthermore, the second fuel store 34 has, for example, a fuel 30 which has a lower proportion of elemental aluminum relative to the other fuels 28 , 32 . The second fuel store 34 also has, for example, a fuel 32 that is a standard fuel and preferably has a proportion of elemental aluminum that is lower than that of the fuel 28 with an increased proportion of elemental aluminum and higher than the fuel 30 with a lower proportion of elemental aluminum is.

The second fuel discharge 38 discharged from the second fuel store 34 is a mixture of the fuels 28, 30, 32 of the second fuel store 34. Preferably, the fuels 22-32 comprise alternative fuels, such as waste, which preferably has a proportion of composite packaging with a high content of has elemental aluminum.

The fuels 22 - 32 have, for example, different contents of elemental aluminum, which are stored in the analysis device 40 in particular.

The first fuel discharge 36 is, for example, fed to the calciner 12 and the second fuel discharge 38 to the furnace firing system 20 .

The system 10 also includes an analysis device 40 for analyzing a material sample.

A material sample 42 is preferably supplied to the analysis device 40 .

The material sample 42 preferably comprises material taken from the calciner 12 and/or the cooler 16 .

It is also conceivable that the material sample 42 comprises material taken from the furnace 14 .

The sample material 42, in particular the cement clinker removed from the plant 10 and/or the precalcined raw material, is preferably stored in a sample container.

In particular, the sample material is homogenized by a mixing device of the analysis device.

The system 10 preferably comprises a sampling device, not shown in FIG. 1, which is designed in such a way that it takes a material sample at a predetermined location in the system.

The sampling device can, for example, be operated automatically or manually.

The analysis device 40 comprises in particular a pressure sensor for determining the gas pressure prevailing in the container with the sample material after activation by an activation liquid, such as KOH solution//NaOH solution, in particular the gas pressure inside the sample container.

The analysis device 40 also comprises, or alternatively, a detector for detecting hydrogen gas, in particular for determining the amount of in the material sample

42 contained hydrogen gas contained after activation with an activation liquid. The analysis device 40 preferably includes a dosing unit for preferably superstoichiometric dosing of an activating fluid, such as, for example, an alkali hydroxide solution or an alkaline solution, into the material sample 42, in particular the sample container. The analysis device 40 is preferably designed in such a way that it determines the amount of hydrogen gas and/or the amount of elementary aluminum in the material sample. For this purpose, the activation fluid is preferably supplied to the sample material over-stoichiometrically by means of the dosing unit. The activation fluid is, for example, a solution containing alkali hydroxide, such as potassium hydroxide solution and/or sodium hydroxide solution. The activation fluid reacts with the sample material to form, among other things, hydrogen gas. . However, it is also conceivable that alkali metal hydroxide as a powder or tablet and water are added to the sample separately. A reaction equation of the reaction of the cement clinker or the pre-calcined raw material of the sample material with the activating fluid is as follows: Al + KOH + 3 H20 = K[Al(OH)4] + 1.5 H2 (1) The analysis device 40 is preferably designed in such a way that it is of the detector detects the amount of hydrogen gas produced by the above reaction. The amount of hydrogen gas is a measure of the elemental aluminum contained in the material sample 42 . The analysis device 40 calculates the amount of elementary aluminum in the material sample 42 from the determined amount of hydrogen gas, preferably via a calculation operation stored in the analysis device or in a connected computer system 40. The amount of hydrogen gas in the sample material is preferably measured over a period of about 2 - Determined continuously for 60 minutes, preferably over 60-240 minutes and for example over a period longer than 240 minutes.

Analysis device 40 is preferably connected to first and/or second fuel store 18, 34 for controlling/regulating first and/or second fuel discharge 36, 38. Preferably, the fuel discharge 36, 38, in particular the amount of fuel discharge 36, 38 and / or

Material composition of the fuel discharge 36, 38 and/or the amount of elemental aluminum in the fuel discharge 36, 38 as a function of the amount of hydrogen gas and/or elemental aluminum in the material sample 42 determined by the analysis device 40 is controlled/regulated.

The analysis device 40 is preferably designed in such a way that it compares the determined gas pressure, the determined amount of hydrogen gas and/or the determined amount of elemental aluminum with a respective predetermined limit value. If the determined gas pressure, the determined amount of hydrogen gas and/or the determined amount of elemental aluminum deviates from the respective limit value, the amount of elemental aluminum in the fuel discharge 36, 38 is increased or decreased. For example, the amount of elemental aluminum in the fuel exhaust 36, 38 is reduced when the gas pressure exceeds the gas pressure limit. The elemental aluminum content of the fuel discharge 36 38 is increased, for example, when the gas pressure falls below the gas pressure limit value. The outlet openings of the stores for the different fuels 22 - 32 are preferably controlled/regulated as a function of the determined quantity of elemental aluminum and/or the gas pressure. In FIG. 1, the stores of the fuels 22-32 are connected to the analysis device 40 via data lines 44, 46. The fuel discharge 36, 38 is preferably formed from certain proportions of the different fuels 22 - 26 and 28 to 32, which are each weighed by weighing devices 48, 50 and then fed to the calciner 12 or the furnace 20 as fuel discharge 36, 38.

It is also conceivable that the analysis device 40 for controlling/regulating the fuel discharge 36, 38 is connected to the respective weighing device 48, 50. Fig. 2 shows a section of a plant 11 for handling cement. The plant 11 has a handling device 52, such as a crushing device for grinding or crushing the cement, in particular the cement clinker, or a mixing plant for mixing a cement from cement clinker and additives or different cements. In Fig. 2 are elements in the

Substantially correspond to those in FIG. 1 and are identified by the same reference symbols. The system 11 has two cement beds 56, 58, each containing a cement, one of the cements, for example the cement of the first cement bed 56, having a lower proportion of elemental aluminum than the other cement of the second cement bed 58. The system 11 has des Furthermore, an analysis device 40, which is designed for the analysis of a material sample 42 as described with reference to FIG. The material sample 42 of the exemplary embodiment in FIG. 2 is removed, for example, from the handling device 52 and analyzed by means of the analysis device 40 . The cement discharge 60 for feeding into the handling device 52 is preferably controlled/regulated as a function of the values determined by means of the analysis device 40, as described with reference to FIG.

The systems 10, 11 described in FIGS. 1 and 2 enable the proportion of elemental aluminum in a cement clinker to be adjusted in a targeted manner, with the control/regulation of the fuel discharge, in particular the proportion of elemental aluminum in the fuel discharge, taking place during the cement production or handling process .

LIST OF REFERENCE NUMERALS 10 plant for the production of cement clinker 11 plant for handling cement clinker 12 calciner 14 kiln 16 cooler 18 first fuel store 20 kiln firing 22 first fuel with an increased proportion of elemental aluminum 24 first fuel with a lower proportion of elemental aluminum 26 first fuel with a medium proportion of aluminum (standard fuel) 28 second fuel with an increased proportion of elemental aluminum 30 second fuel with a lower proportion of elemental aluminum 32 second fuel with a medium proportion of aluminum (standard fuel) 34 second fuel store 36 first fuel outlet 38 second fuel outlet 40 analysis device 42 material sample 44 data line 46 data line 48 Weighing devices 50 weighing devices 52 handling device 54 cement discharge 56 first cement store 58 second cement store

Claims (12)

patent claims 1. A method for operating a plant (10, 11) for producing and/or handling cement, comprising the steps: - taking a material sample (42) of cement clinker from a plant (10, 11) for producing and/or handling cement, - Dosing an activating fluid to the material sample (42), characterized by - determining the gas pressure and/or the amount of hydrogen gas and/or the amount of elemental aluminum in the mixture of the activating fluid and the material sample (42), and - controlling/regulating the fuel discharge (36, 38) from a fuel store (18, 34) for feeding into a firing device (12, 14) of the plant (10, 11) for the production of cement depending on the gas pressure determined and/or the quantity of hydrogen gas determined and /or elementary aluminum or - controlling/regulating the cement discharge (54) from a cement store (56, 58) for feeding into a handling device (52) of the installation (10,11) for handling cement in Dependence of the determined gas pressure and/or the determined amount of hydrogen gas and/or elemental aluminum. 2. The method according to claim 1, wherein the activating fluid comprises an alkali hydroxide solution or a lye. 3. The method according to any one of the preceding claims, wherein the amount of elemental aluminum in the material sample (42) is calculated from the determined amount of hydrogen gas. 4. The method according to any one of the preceding claims, wherein the amount of elemental aluminum of the fuel discharge (36, 38) or the cement discharge (54) is controlled / regulated. 5. The method according to any one of the preceding claims, wherein the determined gas pressure, the amount of hydrogen and / or the amount of elemental aluminum is compared with a respective limit value and a deviation of the determined pressure, the amount of hydrogen and / or the amount of elemental aluminum from the limit value, the amount of elemental aluminum in the fuel discharge (36, 38) or the cement discharge (54) is increased or decreased. 6. The method according to any one of the preceding claims, wherein the material sample (42) from a preheater and / or a cooler of the plant (10) for the production of cement clinker is removed. 7. The method according to any one of the preceding claims, wherein the amount of hydrogen gas in the material sample (42) is determined over a period of about 2 to 240 minutes, preferably 2 to 45 minutes, in particular more than 240 minutes. 8. The method according to any one of the preceding claims, wherein the fuel output (36, 38) from a plurality of fuels (22-32) with different proportions of elemental aluminum is produced. 9. Plant (10, 11) for the production and/or handling of cement clinker, having a fuel store (18, 34) or a cement store (56, 58) with an outlet for discharging a fuel discharge (36, 38) from the fuel store (18, 34) or a cement discharge (54) from a cement store (56, 58), a firing device (12, 14) which is connected to the fuel store (18, 34) for supplying the fuel discharge (36, 38; 54) and/or a handling device (52) which is connected to the cement store (56, 58) for supplying the cement discharge (54), and an analysis device (40) for analyzing a material sample (42) which is connected to the outlet of the fuel store (18, 34 ) Or the cement camp (56, 58) is connected in that they discharge the fuel (36, 38; 54) from the fuel store (18, 34) or the cement discharge (54) from the cement store (56, 58), characterized in that the analysis device (40) is designed in such a way that it measures the amount of hydrogen gas and/or the gas pressure in the Determined material sample and the fuel discharge (36, 38) or the cement discharge (54) depending on the determined amount of hydrogen gas and / or the determined gas pressure controls / regulates. 10. Plant (10, 11) according to claim 9, wherein the analysis device (40) is designed such that it calculates the amount of elemental aluminum in the material sample (42) from the determined amount of hydrogen gas. 11.Anlage (10, 11) according to claim 9 or 10, wherein the analysis device (40) is designed such that it the amount of elemental aluminum of the fuel discharge (36, 38) or the cement discharge (54) depending on the determined amount Hydrogen gas and / or the determined gas pressure controls / regulates. 12. Plant (10, 11) according to any one of claims 9 to 11, wherein the fuel store (18, 34) comprises a plurality of fuels arranged in separate areas or stores within the fuel store (18, 34).