EP4153788A1 - Method and device for dry granulation - Google Patents

Abstract

The invention relates to a method for dry granulation of molten material, wherein particles produced from this material are cooled in at least one fluidised bed by means of process gas and, at least in the fluidised bed which the particles enter directly after they are produced, the process gas is fed into the fluidised bed in a plurality of separate zones. The invention also relates to a corresponding granulator and a signal processing device, a machine-readable program code, a storage medium for the program code and a computer program product therefor.

Description

description

Description of the invention Process and device for dry granulation

Field of technology

The invention relates to a method for dry granulation of molten material and a granulator.

Background Art Dry granulation of molten material is a technology under development for converting molten material into solid granules. Molten material is, for example, molten metal or metallurgical slag, for example molten blast furnace slag - the process is then also called dry slag granulation DSG and is described, for example, in EP2747920B1. In this context, dry means that the molten material does not come into direct contact with liquid water during granulation - this is in contrast, for example, to conventional industrial processes for granulating blast furnace slag, in which the molten slag is introduced into a stream of water. The granulator is a container delimited by an envelope, which has a slag feed, a gas feed for the process gas and an exhaust line for heated process gas - also called process exhaust gas in the context of this application - for example air - also called process air. The molten one Material, for example liquid slag, is applied to an atomization unit located in the casing of the granulator; this is, for example, a rapidly rotating unit known as a rotary atomiser; something like this is shown for example in EP2747920B1. Due to the forces that occur, the molten material is torn into fine droplets and thrown outwards. These fine, initially still molten droplets are cooled and solidified in the granulator, this happens for example through the process gas and when they hit surfaces of the granulator - possibly cooled -, for example the water-cooled casing of the granulator - as a result, solid particles are formed, called granules here can then be removed from the granulator. According to a known working method, liquid or partially solidified - that is, partly liquid, partly solidified - drops in the granulator after leaving the rotary atomizer and then hitting the shell of the granulator down into a fluidized bed. The particles are solidified throughout the fluidized bed. Process gas flows through the fluidized bed against gravity. As a result, the particles are put into a fluidized state, and the amount flowing through takes on properties that are practically fluid-like, which is also called fluidizing and is a well-known principle in process engineering. Starting from a state called fixed bed, in which the process gas flows through a bulk material without fluidizing it, the fluidization begins with increasing process gas speed at a defined point. The one in one

Fluidized bed type of fluidization depends essentially on the gas velocity, gas density as well as on the particle bulk density, the shape, and the grain size distribution of the particles. The term fluidized bed is to be equated with the term fluidized bed, the two terms are used synonymously in the present application. At the fluidization point there is a transition from a fixed bed to a fluidized bed.

The granulator comprises devices for introducing process gas which is intended to serve to form a fluidized bed or a fluidized bed from particles. Fluidized bed cooling of this type is advantageous because in a fluidized bed, due to the high convection and the volume / surface area of the particles, a lot of heat can quickly be given off into the process gas and carried away with the process gas flow. In addition, the movement of a fluidized bed ensures that freshly arriving particles - which are still particularly hot and therefore at least partially soft and sticky and therefore tend to agglomeration - do not linger on the surface of the fluidized bed, but move to other locations or into it Be mixed inside the fluidized bed. This will make the

Probability of meeting and agglomeration of several drops or still hot, not fully solidified - and therefore sticky - particles arriving one after the other on the surface of the fluidized bed is almost completely eliminated. Agglomeration of the particles would encourage them to grow into larger, heavier particles that would seriously affect the process.

Dry granulation with fluidized bed cooling offers the possibility of recovering the heat transferred to the process gas during the cooling of the particles. Conventional granulation technologies based on fluidized bed cooling for dry granulation of molten material, such as liquid blast furnace slag, with rotary atomizers and use of an impact on the casing have a large diameter, since to avoid agglomeration of liquid and / or partially solidified droplets and / or completely solidified particles during the Flight from

Rotary atomizer to the envelope or, after striking the envelope, the distance between the envelope - which is usually arranged rotationally symmetrically to the rotary atomizer and therefore usually round in cross section - has to be selected to be sufficiently large. A greater distance leads to a fanning out of the flow of droplets or particles emanating from the rotary atomizer, so that they fly less close to one another or impinge less close to one another. This reduces the risk of agglomeration during flight or upon impact. Agglomeration can occur on impingement, for example, if completely or partially liquid particles are deformed on impingement and thus come into contact with neighboring particles. Since the particles fall downwards following the force of gravity after they hit the envelope, the size of the area of impact also influences the area of the fluidized bed, which must exist at least below the area of impact. Furthermore, the area required for a desired cooling potential is also influenced by how the temperature and mass flow and thus the heat input of the particles into the fluidized bed are pronounced, and which gas velocity ranges for maintaining a

Fluidized bed for the size distribution of particles are necessary. With a limited maximum speed of the gas flow, for example, a desired increased cooling effect an increase in the base area of the fluidized bed may be necessary for the purpose of increasing the amount of gas that can be introduced into the fluidized bed at the maximum gas velocity.

The height of a fluidized bed is limited by the pressure loss that occurs in the gas flowing through it from bottom to top. This pressure loss, caused by the establishment of the fluidized bed state when flowing through, specifies which pressure is to be provided when introducing in order to maintain the gas flow necessary for the desired cooling effect. The higher the pressure to be applied, the higher the

Energy consumption for introducing the gas. The higher the fluidized bed, the greater the pressure loss. Structural conditions can also limit the realizable height of the fluidized bed.

As a result, with conventional granulation technologies based on fluidized bed cooling for dry granulation of molten material - such as blast furnace slag - with rotary atomizers, the base area to height ratio is relatively large compared to others

Fluidized beds for processes using heat and / or mass transfer, such as FINEX® fluidized bed reduction.

With a large base area and, at the same time, a low height of the fluidized bed, however, problems arise with such dry granulation. For example, local breakdown of the fluidized bed can occur as a result of inhomogeneities in the granulation process which, for example, cause non-rotationally symmetrical distribution of the particles falling from the envelope with respect to the cross section of the fluidized bed; for the formation of hotspots as a result of poor horizontal mixing due to weak related turbulence in the fluidized bed; to uneven fluidization, especially when starting up the fluidized bed. Such problems can greatly encourage agglomeration because local accumulations of droplets or hot, sticky particles can occur that are not quickly cooled to complete solidification. Agglomerates that are too large can impair the maintenance of the fluidized bed and require operations to be stopped in order to remove them. To avoid problems due to uneven fluidization, the process gas supply - or the air supply when using air as the fluidizing or cooling gas - to the fluidized bed has been provided with a pressure that allows the fluidized bed to be sufficiently pronounced even in poorly fluidized areas. The disadvantage here is that well-fluidized areas are supplied with a pressure above the pressure they require - this leads to higher energy consumption for the pressure-generating units and reduces the scope for varying the gas flow through the fluidized bed. It also increases the amount of process gas passed through these areas, which is unfavorable for heat recovery from the process gas due to the lower temperature.

Summary of the Invention Technical Problem

It is therefore an object of the present invention to present apparatus and methods which at least partially reduce or solve such problems.

Technical solution This task is solved by a

Process for dry granulation of molten material, whereby particles produced from this are cooled in at least one fluidized bed by means of process gas, characterized in that at least in that fluidized bed into which the particles enter directly after their generation, the process gas is fed into the fluidized bed in several separate steps Zones takes place.

The molten material comes from one or more mineralogical processes - such as the manufacture of a

Rock melt in a cupola furnace for the production of mineral wool, also called rock wool - and / or from one - or more - metallurgical processes. Preferably the molten material is molten metallurgical

Slag - slag from a metallurgical process. It can also be mixtures of different types of slag. It is, for example, slag as a result of reduction processes of iron girders for iron extraction, such as slag occurring during the operation of blast furnaces or smelting reduction processes - such as COREX® or FINEX®, for example; or it is slag accruing when melting solid products - for example DRI direct reduced iron - from direct reduction processes - this can, for example, be a melting down of DRI in a container - which, for example, does not

LD steelworks converter for the production of crude steel is to act with resistance heating by electrical current and / or by an electric arc, or to melt down DRI in a steelworks converter, for example an LD steelworks converter. It is, for example, slag accumulating in steelworks processes for steel production from iron, for example slag from the operation of LD (BOF), AOD,

EAF. It is preferably slag from the production of pig iron-like melt or pig iron melt - for example by means of

Smelting reduction processes such as COREX® or FINEX® or blast furnace processes - particularly preferably blast furnace slag. It is also preferably slag from a DRI smelting process.

In the course of dry granulation, particles are generated from the molten material. The generation of particles from the molten material takes place by means of an atomizer unit, preferably by means of

Rotary atomizer. In this context, atomization means the generation of particles from the molten material. A rotary atomizer is based on the principle that liquid material is applied to a rotating body, the rotation of the rotating body

Body is transferred to the liquid, and drops are detached from the liquid due to centrifugal forces, i.e. the liquid is atomized.

The term particle includes liquid droplets, partially solidified - that is, partly liquid and partly solid; for example solid on the outside and liquid on the inside - particles, fully solidified particles. Liquid, partially solidified and fully solidified particles can have a stickiness -. Stickiness refers to the ability to adhere or agglomerate with other particles produced during dry granulation. The particles are created from molten material. Molten material has a temperature above its melting point, the particles accordingly contain more heat energy than the solid state. As a result of the cooling, the particles should solidify to such an extent that there is no longer any tendency to agglomerate due to stickiness, which is relevant for the operation of the fluidized bed.

In this context, dry granulation means that the molten material does not come into direct contact with liquid water during granulation. However, liquid water can contribute indirectly to cooling, for example if the shell of the granulator is water-cooled.

The particles generated during dry granulation are cooled in at least one fluidized bed by means of process gas.

It can therefore be cooled in a fluidized bed, or in several fluidized beds; in the case of several fluidized beds, the particles pass through them one after the other.

The process gas can be fed into the fluidized bed in several separate zones in one, some or all of these fluidized beds. The cooling takes place as a for intensive heat exchange

Fluidized bed is supposed to be formed by means of gas, also called process gas here. Air is preferably used as the process gas because it is readily available, also called process air here. The fluidized bed is, for example, a turbulent fluidized bed or an impacting fluidized bed.

According to the invention, the process gas is at least that fluidized bed into which the particles directly after their Generation occur, fed into the fluidized bed in several separate zones. This means the first fluidized bed into which the particles enter after their formation; The formulation immediately after its formation includes that after its formation, other processes take place before the particles first enter a fluidized bed - for example, they hit the envelope before they fall from the envelope into the fluidized bed.

In contrast to a hitherto customary single feed, i.e. feed in a single zone - for example a distributor plate at the bottom of the vessel comprising the fluidized bed, through which gas is fed from a single feed - and thus with a single pressure - the feed does not take place in a single zone but in multiple zones. The separate zones adjoin one another and cover the entire base area of the fluidized bed. With conventional feeding in a single zone, the base of the fluidized bed is covered by this single zone. According to the invention, it is supplied in at least two zones, preferably in at least three zones, particularly preferably at least four zones. For example, it can be fed in two zones or in three zones or in four zones or in five zones or in six zones or in seven zones or in eight zones or in nine zones or in ten zones or in more than ten zones.

Advantageous Effects of the Invention The inventive supply of the process gas into the fluidized bed in several separate zones makes it possible to set different conditions zone by zone; for example by control and / or regulation. For example different pressures can be selected for the supplied process gas in different zones. For example, the volume flow - that is, the volume of process gas supplied to the fluidized bed per unit of time - can be selected differently in different zones. For example, pressure and / or volume flow can be changed zone by zone, possibly independently of other zones. In contrast to conventional feed in a single zone, it is possible to optimize each zone with regard to its needs, for example with regard to pressure and / or

To supply the volume flow with process gas - for example, in an energy-efficient way. Differences between different areas of the fluidized bed with regard to the fluidization can be compensated for or caused automatically by the control system or by manual changes to the parameters by the operating personnel.

For example, a, for example temporarily, causing differences with respect to pressure and / or

Volume flow may be desired in order to compensate for differences in bed height of the fluidized bed between different areas; Such differences can occur, for example, as a result of an asymmetrically distributed impact on the envelope and correspondingly asymmetrically distributed falling into the fluidized bed.

For example, a, for example, temporary,

It may be desirable to produce differences in pressure and / or volume flow in order to compensate for differences in temperature in the fluidized bed between different areas; Such differences can occur, for example, as a result of an asymmetrically distributed impact on the envelope and correspondingly asymmetrically distributed falling into the Fluidized bed occur.

For example, a, for example, temporary,

Causing differences in pressure and / or volume flow may be desired in order to compensate for differences in the degree of fluidization in the fluidized bed between different areas.

For example, a, for example, temporary,

Causing differences in pressure and / or volume flow may be desired in order to bring agglomerates deposited in only one area at the bottom of the fluidized bed into a fluidized state.

For example, a, for example, temporary,

It may be desirable to produce differences in pressure in order to produce uniform process gas distribution in all areas of the fluidized bed; Uneven air distribution can be caused, for example, by blocking individual openings for the supply of process gas, and / or by different particle size distributions in the fluidized bed as a result of asymmetrically distributed impact on the envelope and correspondingly asymmetrically distributed falling into the fluidized bed in connection with poor horizontal mixing of the fluidized bed. Zone-wise divisibility also offers the advantage that an increase in the amount of process gas to eliminate

Irregularities is limited, which is advantageous for achieving the highest possible temperature of the process exhaust gas leaving the granulator. Heat recovery from this process exhaust gas is more efficient at higher temperatures. This means that even when operating fluidized beds with a large base area and the resulting large amounts of process gas Energy recovery from the process exhaust gas is possible in an efficient and economically viable manner.

The process gas is fed into the fluidized bed in several separate zones, but the fluidized bed itself is not divided into partial fluidized beds by devices such as walls, which together form the fluidized bed of the device for dry granulation - mixing would be inhibited, for example, and particles could stick. There is therefore a fluidized bed in which process gas is fed in in several separate zones.

According to a preferred embodiment, in the method the volume flow and / or pressure of the process gas is controlled and / or regulated in at least two zones independently of other zones.

This makes it easier to adapt to local requirements in the fluidized bed. The pressure of the process gas means the pressure under which the process gas is when it is delivered to the fluidized bed.

According to a preferred embodiment, in the method the height of the fluidized bed is determined above, preferably perpendicularly above, at least two zones.

This allows local differences to be determined; based on this, countermeasures can be taken if necessary. The determination can take place directly - by height measurement - or indirectly - by calculation from other types of measured variables. The height of the fluidized bed in an area is determined, for example, based on pressure measurement in the fluidized bed, for example at the bottom of the fluidized bed, in this area. According to a preferred embodiment, in the method the temperature in the fluidized bed is determined over, preferably vertically over, at least two zones. The determination can take place directly - by temperature measurement - or indirectly - by calculation from other types of measured variables. The temperature of the fluidized bed in an area is determined, for example, based on measurements with a thermocouple or a resistance thermometer. This provides information, for example, about the need for cooling in this area of the fluidized bed or about the risk of agglomeration due to the heat-related viscosity or stickiness of the particles. According to a preferred embodiment, in the method the intensity of the fluidized bed is determined over, preferably perpendicularly over, at least one of the zones. The determination can take place, for example, on the basis of measurements of the pressure in the fluidized bed, preferably fixed locally above the floor of the fluidized bed, or evaluation of the course of the pressure development over time. This provides information, for example, about irregularities in the fluidized bed and the mixing, and the associated risk of hot spots or agglomerations or deviations from the desired properties of the granulate, such as bulk density and particle size distribution. The intensity of the fluidized bed results from the time course of the pressure in the fluidized bed or can be read from it. There are various methods for recording the intensity.

The following is a list of possibilities, with other methods of intensity assessments being possible. Detection of the minimum (mini) and maximum (maxi) pressure values occurring within a defined time period A. The difference from maxi to mini is formed and represents the intensity of the fluidized bed. The duration of the selected time period A is between 5 sec (seconds) and 5 min (minutes), preferably between 15 sec and 1 min.

Detection of the minimum (mini) and maximum (maxi) pressure values occurring within a defined time period B. The duration of the selected time period B is between 5 seconds and 5 minutes, preferably between 15 seconds and 1 minute.Determination of an average value of all recorded pressure measurements within a time period C.

The duration of the selected time period C is between 10 sec and 10 min, preferably between 1 min and 3 min. Time period B lies at the end of time period C, but completely in time period C. Time period B is always shorter or equal to time period C. The differences The mean and maxi pressure values are formed and say something about the intensity of the fluidized bed. Determination of a standard deviation - or similar methods of determining deviations - of the recorded measured values for the pressure within a defined time span D. The duration of the selected time span D is between 5 sec and 5 min, preferably between 15 sec and 1 min Intensity.

The greater the value of the intensity, the greater the intensity of the fluidized bed. For example, if the pressure fluctuates strongly around a time average value within a defined period of time, the intensity increases speak, or if there is little fluctuation, of low intensity.

The mentioned features of the height of the fluidized bed, temperature in the fluidized bed, intensity of the fluidized bed can be used to control and / or regulate the process.

The regulation or control can take place, for example, in such a way that deviations from average values or specifications for these parameters as a result of monitoring are perceived at individual measuring points for determining altitude or temperature or intensity - or other parameters. On the basis, for example, the volume flow of the process gas in a zone can be increased if the temperature in the fluidized bed above this zone is too high, or if the temperature is too low, the volume flow can be reduced. The volume flow of the process gas in a zone can also be increased if the height of the fluidized bed above this zone is too great; too many particles are transported away from the area through increased mixing, or if the height is too low, the volume flow is reduced. The volume flow of the process gas in a zone can also be increased if the intensity of the fluidized bed above this zone is too low, or if the intensity is too high, the volume flow can be reduced.

The particles generated during dry granulation are cooled in at least one fluidized bed by means of process gas. It can therefore be cooled in a fluidized bed, or in several fluidized beds; in the case of several fluidized beds, the particles pass through them one after the other. According to an advantageous embodiment of the method according to the invention, cooling to a final temperature is carried out in stages, first in the fluidized bed into which the particles enter directly after their generation, to a primary cooling temperature, and then in at least one further fluidized bed to the final temperature.

According to one of many possible embodiments, process gas is fed into at least one of the further fluidized beds in several separate zones - that is, analogous to the feed into that fluidized bed into which the particles enter directly after their generation.

The further or further fluidized beds can be arranged in series or in parallel with the fluidized bed into which the particles enter directly after their generation, with regard to the supply or flow of the process gas. A combination of serial and parallel arrangements is also possible.

The fluidized bed into which the particles enter directly after their generation is also referred to here as the primary fluidized bed. When they are removed from this fluidized bed, the particles have what is known as the primary cooling temperature.

In one or more further fluidized beds, the particles are cooled further to a final temperature that was present when they were removed from the last fluidized bed.

The particles are removed from the primary fluidized bed and transferred to another fluidized bed - called the first

Subsequent fluidized bed - entered. The temperature of the particles when they are removed from the subsequent fluidized bed is the first subsequent temperature. If after removal from the first

If the subsequent fluidized bed is not fed into a further fluidized bed, the first subsequent temperature is the final temperature. If after removal from the subsequent fluidized bed into another fluidized bed - called the second

Subsequent fluidized bed - is entered, the particles have the second subsequent temperature after cooling in the second subsequent fluidized bed when they are removed from the second subsequent fluidized bed. If, after removal from the second subsequent fluidized bed, no further fluidized bed is added, the second subsequent temperature is the final temperature. Correspondingly, in the case of input into one or more further fluidized beds such as third subsequent fluidized bed, fourth subsequent fluidized bed, fifth subsequent fluidized bed, the end temperature is the temperature that was present when the fluidized bed was taken from the last fluidized bed with regard to the cooling process.

Another fluidized bed can be used, or two, or three, or four, or five, or six more

Fluidized beds, or more than six other fluidized beds.

In this way, a final temperature below the primary cooling temperature can be achieved without increasing the volume flow of the process gas through the primary fluidized bed. Due to the higher temperature of the process exhaust gas discharged from the primary fluidized bed, this allows more efficient heat recovery from this process exhaust gas, and it allows easier handling of the particles because their temperature is below the primary cooling temperature.

According to an advantageous embodiment, the process gas supplied to that fluidized bed into which the particles enter directly after their generation comprises process waste gas from at least one of the further fluidized beds. The process exhaust gas that is provided for supply can also be cleaned and / or cooled prior to supply. In this case, the process gas supplied to that fluidized bed into which the particles enter directly after their generation already contains heat withdrawn from the particles in the further fluidized bed (s). Therefore, the process exhaust gas from this fluidized bed is higher - compared to

Introduction of process gas that has not yet withdrawn any heat from the particles, i.e. has a so-called process gas base temperature - having temperature. This allows more efficient heat recovery from this process exhaust gas. Based on the designations introduced above, the process exhaust gas of that fluidized bed into which the particles enter directly after their generation - that is, the primary fluidized bed - can be referred to as primary exhaust gas. Correspondingly, the process exhaust gas from the first subsequent fluidized bed can be referred to as the first subsequent process exhaust gas; for further subsequent fluidized beds analogously.

According to this embodiment, the process gas supplied to the primary fluidized bed comprises process exhaust gas from at least one of the further subsequent fluidized beds. It can also consist of such a process exhaust gas.

In this way, a higher temperature of the process exhaust gas provided for heat recovery and a lower final temperature of the granulate can be achieved than when using only primary process exhaust gas or using process exhaust gas from only one fluidized bed. This allows more efficient heat recovery.

According to an advantageous embodiment, process exhaust gas is derived from that fluidized bed into which the particles enter directly after their generation, after mixing together with at least a partial amount of the process exhaust gas from at least one of the further fluidized beds. It is preferred to discharge all further fluidized beds together with at least a portion of the process exhaust gas; particularly preferred is to discharge all other fluidized beds together with the entire process exhaust gases.

In this way, a higher temperature of the process exhaust gas provided for heat recovery and a lower final temperature of the granulate can be achieved than when using only primary process exhaust gas or using process exhaust gas from only one fluidized bed. This allows more efficient heat recovery. The same process gas is preferably supplied to the fluidized beds which supply these jointly derived process exhaust gases; for example air at ambient temperature or cooled air, for example air at a temperature of 0 ° C.

As a result of the procedure according to the invention, a fluidized bed with a large base-to-height ratio can be handled well; Operation of dry granulation of molten slag under unfavorable conditions is thereby facilitated or made possible even under conditions restricted by spatial conditions. In addition, the process management according to the invention enables an increased efficiency of the heat recovery from process exhaust gas.

Another object of the invention is a granulator comprising, within an envelope of the granulator, an atomizer unit for generating particles from molten material, a supply device for supplying molten material to the atomizer unit, at least one fluidized bed area with a gas supply for process gas, and at least one gas discharge line for process exhaust gas the fluidized bed area, characterized in that the gas supply has several supply zones at least for the fluidized bed space area which is suitable for the entry of the particles directly after their generation by means of the atomizer unit.

The granulator is a device for dry granulation of molten material.

The granulator is limited by an envelope. The atomizer unit is used to atomize the molten material. In this context, atomization means the generation of particles from the molten material.

A fluidized bed area is designed to form a fluidized bed from particles formed by the atomizer unit from the molten material with gas - this gas is process gas for the respective fluidized bed; the process gas for a fluidized bed can also be process exhaust gas from another fluidized bed. The fluidized bed area is suitable for cooling the particles by means of process gas.

There is at least one fluidized bed room area; several fluidized bed room areas can also be present. At least one fluidized bed space area, preferably only one fluidized bed space area, is suitable for the entry of the particles directly after they have been generated by means of the atomizer unit. At least for that person

The area of the fluidized bed chamber, which is suitable for the entry of the particles directly after their generation by means of the atomizer unit, has the gas supply line having several supply zones; the

Feed zones are separated from one another. They are used to feed process gas into the fluidized bed area in several separate zones. The granulator comprises a device for controlling and / or regulating the volume flow of the process gas. The granulator preferably comprises a device for independently controlling and / or regulating the volume flow and / or the pressure of the process gas in at least two zones; This means two zones that feed process gas into the same fluidized bed area. The granulator preferably comprises a device for determining the height of a fluidized bed formed during operation in the fluidized bed space region over at least two feed zones. This device includes, for example, a pressure gauge.

The granulator preferably comprises a device for determining the temperature of a fluidized bed formed in the fluidized bed space region during operation via at least two feed zones. This device includes, for example, a thermocouple and / or a resistance thermometer.

The granulator preferably comprises a device for determining the intensity of a fluidized bed formed during operation in the fluidized bed space region over at least one feed zone. This device includes, for example, a pressure gauge.

The mentioned devices for determining the altitude, the temperature, the intensity of the fluidized bed are preferably suitable for transmitting data to the mentioned devices for controlling and / or regulating. The granulator preferably comprises several

Fluidized bed space areas. It can comprise two, or three, or four, or five, or six, or seven fluidized bed space areas, or more than seven fluidized bed space areas. The further or further fluidized bed space areas can be arranged in series or in parallel with that fluidized bed room area which is suitable for the entry of particles directly after their generation by means of the atomizer unit with regard to the supply or flow of the process gas. A combination of serial and parallel arrangements is also possible.

According to a variant, the gas supply for the fluidized bed space area, which is suitable for the entry of particles directly after their generation by means of an atomizer unit, has at least one opening of a gas discharge line from at least one other fluidized bed space area. According to a variant, the gas discharge has the

Fluidized bed space area, which is suitable for the entry of particles directly after their generation by means of an atomizer unit, at least one mouth of a gas discharge line from at least one other fluidized bed space area.

According to a variant, the gas feeds to these fluidized bed space areas start from a single gas feed line - they therefore originate from a common gas feed line. In principle, you can also start from different gas feed lines. Of course, the granulator also includes one or more removal devices for removing granules formed during operation from the fluidized bed room areas. Another subject matter of the present application is a signal processing device with a machine-readable program code, characterized in that it has control and / or regulating commands for carrying out a method according to the invention. Another subject matter is a signal processing device for carrying out a method according to the invention.

Another subject matter of the present application is a machine-readable program code for a signal processing device, characterized in that the program code has control and / or regulating commands which cause the signal processing device to carry out a method according to the invention. Another subject matter is a computer program product comprising instructions for a signal processing device which, when the program is executed, for the

Signal processing device cause these to carry out a method according to the invention. Another object of the present application is a

Storage medium with a machine-readable program code according to the invention stored thereon. Another subject matter is a storage medium with a computer program stored on it for carrying out a method according to the invention.

Another subject matter of the present application is a computer program product which comprises a program and can be loaded directly into a memory of a granulator, with program means to regulate and / or control the granulator in accordance with a method according to the invention when the program is executed by the regulating device and / or control device.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be explained in more detail on the basis of exemplary embodiments. The drawings are exemplary and are intended to explain the concept of the invention, but in no way restrict it or reproduce it conclusively. It shows:

1 shows a schematic side view of a section through a granulator according to the invention.

FIG. 2 shows a schematic view of FIG. 1 from above with a representation of devices for controlling and / or regulating.

3 shows a block flow diagram of a serial fluidized bed arrangement.

4 shows a block flow diagram for a parallel fluidized bed arrangement.

Description of the embodiments

EXAMPLES FIG. 1 shows a schematic side view of a section through a granulator 1 according to the invention. The granulator 1 has a casing 2; In the variant shown, the areas of the envelope on which the particles impinge are water-cooled. An atomizer unit 3, for example a rotary atomizer, is arranged in the granulator 1. Molten material, for example blast furnace slag, is supplied via a supply device 4 for supplying molten material to the atomizer unit 3. A stream of particles generated by means of the atomizer unit 3, which hits the casing and particles falling from the casing, are shown in dashed lines. The falling particles fall into a fluidized bed 5 - represented by dots - which, in the variant shown, extends symmetrically around the atomizer unit 3. In the operating state shown, the fluidized bed 5 is formed in a fluidized bed space region 6 of the granulator 1. The fluidized bed 5 is shown, into which the particles enter directly after their generation. Process gas, in the illustrated case process air at ambient temperature, is fed to the fluidized bed space region 6 or the fluidized bed 5 with a gas feed 7. The gas supply has several supply zones 7a, 7b; the supply of the process gas - shown with block arrows - into the fluidized bed 5 thus takes place in several separate zones. Process exhaust gas from the fluidized bed area 6 is discharged from the granulator 1 via the gas discharge line 8. The granulate discharge 9a and 9b takes place contrary to the process gas flow at several points below the fluidized bed.

FIG. 2 shows a schematic view from above of a granulator 1 as in FIG. 1. There are 4 separate zones 10a, 10b, 10c, 10d in which process gas is fed into the fluidized bed (not shown separately) in four feed zones, and a device for controlling and / or regulating 11 the volume flow F of the process gas; controlling and / or regulating takes place in the example shown in all zones independently of other zones.

Devices for determining the height of the fluidized bed above the zones 10a, 10b, 10c, 10d are available and designed as pressure gauges P; the pressure gauges also serve as components of devices for determining the intensity over the zones 10a, 10b, 10c, 10d - if necessary, the determination is made in connection with the device for controlling and / or regulating 11. devices for determining the temperature of the fluidized bed over the zones 1Oa, 1Ob, 1Oc, 1Od are available and as

Executed thermocouples T and / or resistance thermometers. Supplied process gas is indicated with a block arrow.

FIG. 3 schematically shows an arrangement with several fluidized bed space areas 12a, 12b, 12c arranged in series with respect to the process gas flow. Cooling to a particle _{primary cooling temperature T PP} takes place first in the fluidized bed area 12a in that fluidized bed into which the particles - the particle flow is shown by straight arrows - enter directly after their generation, i.e. the primary fluidized bed. _{This is followed by cooling to the intermediate temperature T PX} and finally to the particle end _{temperature T PE} in the further fluidized beds or subsequent fluidized beds in the fluidized bed space regions 12b, 12c. Process exhaust from the

Primary fluidized bed - the process gas flow is shown by jagged arrows - has the temperature T _GP . Process exhaust gas from the subsequent fluidized bed in fluidized bed space region 12b has the intermediate temperature T _GX . Process gas from the subsequent fluidized bed in fluidized bed space area 12c has the temperature T _GE .

Particles or granules from the subsequent fluidized bed in fluidized bed space area 12c have the temperature T _PE . Particles or granules from the primary fluidized bed in fluidized bed space area 12a have the temperature T _PP .

Particles or granules from the subsequent fluidized bed in fluidized bed space area 12b have the intermediate temperature T _PX .

The process exhaust gas from the fluidized bed space region 12c is process gas from the fluidized bed space region 12b. The process exhaust gas from the fluidized bed space region 12b is process gas from the fluidized bed space region 12a. Since the respective gas supply lines are at the same time the gas discharge lines of another area of the fluidized bed space, they have an opening of a gas discharge line from another area of the fluidized bed space.

FIG. 4 schematically shows an arrangement with a plurality of fluidized bed space areas 13a, 13b, 13c with respect to

Process gas flow arranged in parallel. Process exhaust gas from that fluidized bed into which the particles enter directly after their generation - i.e. the primary fluidized bed - in fluidized bed area 13a is after mixing together with at least a portion of the process exhaust gas from the two further fluidized beds - or

Subsequent fluidized beds - derived in the fluidized bed space areas 13b and 13c. The same process gas is fed to the primary fluidized bed and the subsequent fluidized beds via the gas feed line 14, which branches off accordingly. The flow of particles into the primary fluidized bed, from the primary fluidized bed into the subsequent fluidized bed in fluidized bed area 13b, from there into the subsequent fluidized bed in fluidized bed area 13c, and from the subsequent fluidized bed in fluidized bed area 13c is shown with thick arrows. In the primary fluidized bed the particles are cooled to the primary temperature T _PP , in the subsequent fluidized bed in the fluidized bed area 13c to the Final temperature T _PE . Exhaust gas 15 from the subsequent fluidized bed in fluidized bed area 13c has the final temperature T _GE, exhaust gas 16 from the primary _{fluidized bed has the primary temperature T GP.} These two exhaust gases are discharged from the granulator together with the exhaust gas from the fluidized bed area 13b - with a temperature T _GX from the cooling of the particles to the temperature T _PX - achieve a mixed temperature T _GPE, the respective gas discharge lines merge.

List of reference symbols

1 granulator

2 wrapping

3 atomizer unit

4 feeding device

5 fluidized bed

6 vertebral layer spatial area

7 Gas supply

7a, 7b feed zones 8 gas discharge

9a, 9b granule ejection rag

10a, 10b, 10c, 10d zones 11 device for controlling and / or regulating

12a, 12b, 12c vortex layer spatial areas 13a, 13b, 13c vortex layer spatial areas

14 gas feed line

15 exhaust gas from the

Subsequent vortex layer

16 exhaust gas from the

Primary fluidized bed

Claims

Expectations

1. A method for dry granulation of molten material, the particles generated from this being cooled in at least one fluidized bed by means of process gas, characterized in that the process gas is fed into the fluidized bed at least in that fluidized bed into which the particles enter directly after their generation several separate zones.

2. The method according to claim 1, characterized in that the volume flow and / or pressure of the process gas is controlled and / or regulated in at least two zones independently of other zones.

3. The method according to claim 1 or 2, characterized in that the height of the fluidized bed is determined above, preferably perpendicularly above, at least two zones.

4. The method according to any one of claims 1 to 3, characterized in that the temperature in the fluidized bed is determined over, preferably vertically over, at least two zones.

5. The method according to any one of claims 1 to 4, characterized in that the intensity of the fluidized bed is determined over, preferably perpendicularly over, at least one of the zones.

6. The method according to any one of claims 1 to 5, characterized in that stepwise cooling to a final temperature takes place, first in the fluidized bed in which the particles enter directly after their generation, to a primary cooling temperature, and then in at least one further fluidized bed to the Final temperature.

7. The method according to any one of claims 1 to 6, characterized in that process exhaust gas from that fluidized bed into which the particles enter directly after their generation, after mixing together with at least a portion of the process exhaust gas from at least one of the further fluidized beds is derived.

8. Granulator comprising within an envelope of the granulator an atomizer unit for generating particles from molten material, a supply device for supplying molten material to the atomizer unit, at least one fluidized bed area with a gas supply for process gas, and at least one gas discharge for process exhaust gas from the fluidized bed area, characterized that at least for the fluidized bed space area, which is suitable for the entry of the particles directly after their generation by means of the atomizer unit, the gas supply has several supply zones.

9. Granulator according to claim 8, comprising a device for independently controlling and / or regulating the volume flow and / or the pressure of the process gas in at least two feed zones.

10. Granulator according to claim 8 or 9, characterized in that the granulator comprises a device for determining the height of a fluidized bed formed during operation in the fluidized bed space region over at least two feed zones.

11. Granulator according to one of claims 8 to 10, characterized in that the granulator has a device for determining the temperature of a during operation in the Comprises fluidized bed formed fluidized bed area over at least two feed zones.

12. Granulator according to one of claims 8 to 11, characterized in that the granulator has a device for determining the intensity of a during operation in the

Comprises fluidized bed formed fluidized bed area above at least one feed zone.

13. Granulator according to one of claims 8 to 12, characterized in that the granulator comprises several fluidized bed space areas.

14. Granulator according to one of claims 8 to 13, characterized in that the gas discharge of the

Fluidized bed space area, which is suitable for the entry of particles directly after their generation by means of an atomizer unit, has at least one mouth of a gas discharge line from at least one other fluidized bed space area.

15. Signal processing device with a machine-readable program code, characterized in that it has control and / or regulating commands for carrying out a method according to one of claims 1 to 7.