BE1027675B1 - Cooler and method for cooling bulk goods - Google Patents

Abstract

The present invention relates to a method for cooling bulk material, in particular cement clinker, in a fine material cooler (22) having the following steps: - Letting in bulk material to be cooled through a material inlet (30) into the fine material cooler (22), the bulk material having a fine material fraction of 70 % to 90%, in particular 75% to 85%, preferably 80%, conveying the bulk material to be cooled in the conveying direction (F) through the fine material cooler (22) to a material outlet (32). The invention also relates to a cooler (10) for cooling bulk material, in particular cement clinker, having a cooler inlet (12) for admitting bulk material to be cooled into the cooler (10), one arranged in the conveying direction (F) of the bulk material behind the cooler inlet (12) Separation area (16) for separating coarse material and fine material, a coarse material cooler (20) following the separation area (16) for cooling the coarse material and a fine material cooler (22) connected to the separation area (16) and connected in parallel to the coarse material cooler (20) for cooling the fine material, characterized in that the fine material cooler (22) has a first conveying unit for conveying coarse material and a second conveying unit for conveying fine material.

Description

Cooler and method for cooling bulk goods The invention relates to a method and a cooler for cooling bulk goods, in particular cement clinker.

For cooling hot bulk material, such as cement clinker, for example, it is known that the bulk material is placed on an aeration base of a cooler through which a cooling medium, such as cooling gas, can flow. The hot bulk material is then moved from one end of the cooler to the other end for cooling and cooling gas flows through it. It is known to use a fluidized bed cooler or a fluidized bed cooler, for example, for cooling fine material. A fines cooler is known, for example, from EP 0 576 053 A1. Such a fine material cooler is only suitable for fine material. If, in addition to the fine material, coarse material also gets into the fine material cooler, the cooling efficiency of the fine material cooler is significantly reduced, since the removal of the coarse material is made more difficult and the fine material cooler can become clogged by the coarse material. A conveyance of the coarse material to the material outlet of the fine material cooler is therefore often only possible manually. In particular in a separation cooler, in which fine material and coarse material are cooled separately from one another, it is therefore necessary that the fine material and the coarse material are completely separated so that the fine material cooler is filled exclusively with fine material. Such a complete separation is very costly. Based on this, it is the object of the present invention to provide a cooler and a method for cooling bulk material, in particular a fine material cooler for cooling fine material, which is preferably particularly well suited for use in a separation cooler. According to the invention, this object is achieved by a method for cooling bulk material with the features of independent method claim 1, as well as by a cooler with the features of independent device claim 7. Advantageous developments result from the dependent claims. According to a first aspect, a method for cooling bulk material, in particular cement clinker, in a fine material cooler has the following steps:

Letting in bulk material to be cooled through a material inlet into the fine material cooler, the bulk material having a fine material content of 70% to 95%, in particular 75% to 85%, preferably 80%, and conveying the bulk material to be cooled in the conveying direction through the fine material cooler a material outlet, wherein the bulk material is preferably cooled in the cross flow during conveyance in the conveying direction. The fine material cooler is arranged, for example, in a cooler for cooling bulk material, the cooler being a separation cooler in which fine material and coarse material are cooled essentially separately from one another. The cooler preferably has a cooler inlet for admitting bulk material to be cooled into the cooler, a separation area arranged downstream of the cooler inlet in the conveying direction of the bulk material for separating coarse material and fine material, a coarse material cooler adjoining the separation area for cooling the coarse material and one adjacent to the separation area subsequent fine material cooler connected in parallel to the coarse material cooler for cooling the fine material. In particular, a furnace for burning cement clinker is connected upstream of the cooler, the burnt cement clinker falling from the furnace through the material inlet into the cooler. A method for cooling bulk material in such a cooler comprises the steps: admitting bulk material to be cooled from an oven through a material inlet into the cooler, separating fine material and coarse material in a separation area of the cooler, the coarse material having a grain size that is larger than that of the fine material, cooling the fine material in a fine material cooler with a cooling medium and cooling the coarse material in a coarse material cooler separately from the fine material.

The cooler inlet area, for example, adjoins the material inlet and has, for example, a static grate which is arranged below the furnace outlet so that the bulk material emerging from the furnace falls onto the static grate due to gravity. The static grate is, for example, a grate set at an angle to the horizontal of 10 ° to 35 °, preferably 12 ° to 33 °, in particular 13 ° to 21 °, through which cooling air flows from below.

In the direction of flow of the bulk material to be cooled, for example, the material inlet or the static grate of the cooler inlet area is directly followed by the separation area, in which the fine and coarse material of the bulk material are separated and then cooled separately from one another.

The separation area has, for example, a static or a dynamic grate.

In addition, the separation area comprises means for separating the fine material from the coarse material of the bulk material.

The fine material is, for example, bulk material with a grain size of about 105mm to 4mm, preferably 105mm to 2mm, the coarse material being bulk material with a grain size of 4mm to 100mm, preferably 2mm to 100mm.

The separating cut between the coarse material and the fine material is preferably at a grain size of 2mm.

The fine material preferably comprises a proportion of 90% to 95% of bulk material with a grain size of 105 mm to 4mm, preferably 10 ° mm to 2mm, with 5% to 10% of the fine material being bulk material with a grain size of more than 2mm, can act preferably more than 4mm.

The coarse material preferably comprises 90 to 95% of bulk material with a grain size of 2mm to 100mm, preferably 4mm to 100mm, with 5% to 10% of the coarse material being bulk material with a grain size of less than 2mm, preferably less than 4mm can act.

The fine material cooler and the coarse material cooler preferably adjoin the separation area, these being arranged parallel to one another.

The parallel arrangement of the fine material cooler and the coarse material cooler is not to be understood geometrically, but in terms of process technology.

The fine material cooler can also be arranged in the geometric sense parallel to the coarse material cooler.

The fine material cooler is preferably connected in parallel to the coarse material cooler in the conveying direction of the bulk material.

The fine material cooler and the coarse material cooler preferably each have a dynamic grate through which a cooling medium flows in order to cool the bulk material resting on the dynamic grate.

The cooling medium is, for example, cooling air that is blown through the fine and coarse material cooler by means of fans.

The admission of bulk material with a fine material content of 70% to 95%, in particular 75% to 85%, preferably 80%, enables efficient operation of a separation cooler, so that a complete separation of the fine material and the coarse material is not necessary.

A separation means is arranged, for example, between the separation area and the fines cooler, the separation means extending completely or partially along a longitudinal side of the separation area. The separation means is preferably designed as a wall.

The separation means has, in particular, a fine material outlet for discharging the fine material from the separation area into the fine material cooler, the fine material outlet preferably being arranged completely above the aeration base of the separation area. The fines outlet of the separation area preferably represents the fines inlet into the fines cooler, the fines cooler, for example, connecting directly to the separation area or via a means of transport for transporting the fines. The coarse material is preferably in the lower area of the bulk material of the separation area, the fine material resting on the coarse material in the upper area. The separation area therefore has an upper fine material area and a coarse material area directly adjoining it below, which adjoins the ventilation base of the separation area. A fine material outlet for discharging fine material from the separation area into the fine material cooler above the ventilation base of the separation area enables fine material to preferably enter the fine material cooler. The fine material outlet is preferably arranged in the fine material area of the separation area in which exclusively or mainly fine material is present. The coarse material area, in which mainly or exclusively coarse material is present, is preferably arranged completely or partially below the fine material outlet so that it cannot pass through the fine material outlet into the fine material cooler due to gravity.

Such an embodiment preferably ensures that less than 10% to 30%, in particular 15% to 25%, preferably 20%, of the incoming material with a particle size greater than 4 mm, preferably greater than 2 mm, reaches the fines cooler. For example, the separation means designed as a wall forms a

Side wall of the separation area and, for example, at the same time a side wall of the coarse material cooler. According to a first embodiment, the fine material of the bulk material is conveyed pneumatically 5. In particular, the fine material is fluidized by means of a flow of cooling air, which is generated, for example, by a plurality of fans, so that it behaves like a liquid mass. The transport of the fine material in the conveying direction is preferably carried out by continuously introducing bulk material into the fine material cooler, so that the fluidized fine material is moved in the conveying direction.

According to a further embodiment, the bulk material has a proportion of coarse material of 5% to 30%, in particular 25% to 15%, preferably 20%, the coarse material being conveyed pneumatically. The coarse material is preferably conveyed by means of compressed air which is generated by a compressed air device such as a compressor. In particular, the fine material and the coarse material are conveyed by different pneumatic conveying units, so that the conveying speed of the fine material and the coarse material is, for example, different and can be set separately from one another. When the fines cooler is in operation, the coarse material settles in the lower area of the bulk material, the upper area of the bulk material being formed by fine material. According to a further embodiment, the compressed air is fed into the fine material cooler via compressed air inlets pointing in the conveying direction, the coarse material being transported in the conveying direction by means of the compressed air. The compressed air inlets are designed, for example, as channels in the ventilation base or as lines and preferably extend exclusively in the area of the fine material cooler in which the coarse material is arranged. According to a further embodiment, the bulk material has a proportion of coarse material of 5% to 30%, in particular 25% to 15%, preferably 20%, the coarse material being conveyed mechanically. The fine material cooler is preferably operated in such a way that the bulk material in the fine material cooler has a height of 100 mm to 400 mm, in particular 200 mm to 300 mm, preferably 250 mm.

According to a further embodiment, the coarse material and the fine material are discharged separately from the fine material cooler. For example, the coarse material is discharged from the fine material cooler through a coarse material outlet and the fine material through a separate fine material outlet. The coarse material outlet is arranged, for example, in front of the fine material outlet in the conveying direction of the bulk material. It is also conceivable that the fine material outlet is arranged in front of the coarse material outlet in the conveying direction. For this purpose, for example, an outflow of the fines from an opening in the ventilation base and / or an opening in the side wall of the fines cooler is suitable. For example, the fine material lying above the coarse material is discharged from the fine material cooler via an overflow. It is also conceivable that the coarse material and the fine material are discharged from the fine material cooler together from a common material outlet.

According to a further embodiment, the bulk material is conveyed exclusively mechanically in a region of the fines cooler at the rear in the conveying direction. The fine material is preferably not conveyed pneumatically in a region of the fines cooler at the rear in the conveying direction. For example, the pneumatic conveying of the fine material, in particular the fluidization of the fine material, does not take place exclusively in the area of the fine material cooler adjoining the material outlet. In the rear area of the fine material cooler, the fine material is deposited on the coarse material, which enables the fine material to be separated by means of an overflow, for example. The area of the ventilation base adjoining the fine material outlet preferably comprises an area without cooling air passages.

The invention also comprises a cooler for cooling bulk material, in particular cement clinker, having a cooler inlet for admitting bulk material to be cooled into the cooler, a separation area arranged in the conveying direction of the bulk material behind the cooler inlet for separating coarse material and fine material, a separation area adjoining the separation area Coarse material cooler for cooling the coarse material and a parallel to the separation area! Fine material cooler connected to the coarse material cooler for cooling the fine material. The fines cooler has a first conveyor unit for conveying coarse material and a second conveyor unit for conveying fine material. Separate conveyance of the fine material and the coarse material enables coarse material and fine material to be cooled together in one cooler, so that a complete separation of fine material and coarse material within the separation area is not necessary. Furthermore, clogging of the fine material cooler is prevented by actively conveying the coarse material.

The embodiments and advantages explained with reference to the cooler for cooling bulk goods also apply in process-related correspondence to the method for cooling bulk goods.

The fines cooler has, in particular, a ventilation base which is designed as a grate, for example, and on which the bulk material rests. The first conveying unit for conveying the coarse material is preferably arranged in such a way that only the coarse material lying on the aeration floor can be conveyed by means of the first conveying unit. The first conveyor unit is preferably arranged in such a way that it only conveys the lower region of the bulk material in which the coarse material is located. The coarse material layer has, for example, a height of 20mm to 200mm, in particular 50mm to 150mm, preferably 100mm. According to a further embodiment, the first conveyor unit for the coarse material is a mechanical or a pneumatic conveyor unit. According to a further embodiment, the second conveyor unit for the fine material is a pneumatic conveyor unit. The mechanical conveyor unit preferably comprises a ventilation base, for example a grate. According to a further embodiment, the mechanical conveying unit has a plurality of conveying elements which can be moved simultaneously in the conveying direction and non-simultaneously against the conveying direction. The conveying elements are, for example, planks, preferably grate planks, which, arranged next to one another, form a ventilation floor. The conveying elements can be moved in the conveying direction F and against the conveying direction F. The conveyor elements designed as conveyor planks or grate planks can preferably be traversed by cooling air, are arranged over the entire length of the fine material cooler and form the surface on which the bulk material rests. It is also conceivable that the mechanical conveyor unit comprises, for example, a stationary ventilation base through which cooling air can flow and a plurality of conveyor elements that can be moved relative to the ventilation base. The conveyor elements are preferably arranged above the aeration floor and point transversely to

Conveying direction running driver.

To transport the bulk material along the aeration base, the conveying elements can be moved in the conveying direction and against the conveying direction.

The conveying elements are preferably movable according to the “walking floor principle”, the conveying elements all being moved simultaneously in the conveying direction and non-simultaneously against the conveying direction.

The conveying elements of the mechanical conveying unit preferably extend exclusively into the area of the bulk material in which the coarse material is present.

The mechanical conveying unit is, for example, a screw conveyor or other conveying units used in bulk material technology.

The screw conveyor preferably extends in the conveying direction above the aeration base.

According to a further embodiment, the pneumatic conveying unit for conveying the fine material has a plurality of fans for subjecting the fine material to a flow of cooling air.

The fans are preferably arranged below the ventilation floor so that the cooling air flow flows through the ventilation floor into the bulk material lying on it.

In particular, the fans are designed and set up in such a way that they fluidize the fine material so that it is preferably transported in the conveying direction by the bulk material let into the fine material cooler.

In addition, the first conveyor unit of the fines cooler is designed, for example, as a mechanical conveyor unit.

According to a further embodiment, the pneumatic conveying unit for conveying the coarse material in the conveying direction has a compressed air device for applying compressed air to the coarse material.

The compressed air device preferably comprises a compressor for generating the compressed air and a plurality of compressed air inlets, which are designed, for example, as channels pointing in the conveying direction.

The compressed air inlets preferably extend through the ventilation base or are arranged above the ventilation base.

The channels pointing in the conveying direction ensure reliable transport of the coarse material along the aeration floor in the conveying direction.

According to a further embodiment, a plurality of guide elements for guiding the fines within the fines cooler are arranged in the fines cooler.

The

Guide elements preferably extend into the area of the bulk material, which mainly comprises fine material. For example, the guide elements are arranged at a distance from the aeration base, so that the coarse material is arranged below the guide elements. For example, the guide elements are at a distance of 20mm to 200mm, in particular 50mm to 150mm, preferably 100mm, from the ventilation base. A plurality of parallel guide elements are preferably arranged at a uniform distance from one another over the entire length of the fines cooler. Alternatively, the guide elements can also be partially attached to the aeration floor and protrude into the bulk material, consisting of coarse material and fine material. This results in deflections when the bulk material is conveyed through the fine material cooler, as a result of which the bulk material flow is mixed locally. The guide elements extend, for example, orthogonally to the conveying direction.

According to a further embodiment, the fine material cooler has a coarse material outlet for discharging coarse material from the fine material cooler and a fine material outlet for discharging fine material from the fine material cooler. The coarse material outlet and the fine material outlet are arranged separately from one another. The coarse material outlet is preferably arranged as a depression in the aeration floor or behind the aeration floor in the conveying direction. In particular, the fine material outlet is arranged behind the coarse material outlet in the conveying direction.

Description of the drawings The invention is explained in more detail below on the basis of several exemplary embodiments with reference to the accompanying figures. 1 shows a schematic illustration of a cooler for cooling bulk goods in a top view according to an exemplary embodiment. FIG. 2 shows a schematic illustration of a cooler for cooling bulk goods in a sectional view according to an exemplary embodiment. 3 shows a schematic illustration of a cooler for cooling bulk goods in a sectional view according to an exemplary embodiment.

4 shows a schematic illustration of a cooler for cooling bulk goods in a sectional view according to an exemplary embodiment. Fig. 1 shows a cooler 10 for cooling hot bulk material, in particular cement clinker. The cooler 10 is preferably arranged downstream of a furnace (not shown in FIG. 1), in particular a rotary kiln, for burning cement clinker, so that hot bulk material emerging from the furnace falls onto the cooler 10, for example as a result of gravity.

The cooler 10 has a plurality of areas, in each of which the bulk material has different temperatures and, for example, is cooled in different ways. The cooler 10 has a material inlet 12 for admitting hot bulk material into the cooler 10. The material inlet 12 is, for example, the area between the furnace outlet and a static grate of the cooler 10, the bulk material preferably falling through the material inlet 12 as a result of gravity. The bulk material to be cooled has a temperature of 1200 to 1450 ° C. in the material inlet 12, for example. A cooler inlet area 14 adjoins the material inlet 12, which area comprises, for example, a static grate. The static grate is, for example, one in one

Angle to the horizontal of 10 ° to 35 °, preferably 12 ° to 30 °, in particular 13 ° to 21 °, inclined grate through which cooling air flows from below.

The static grate is preferably arranged below the furnace outlet, so that the bulk material from the furnace outlet falls directly onto the static grate and slides along it in the conveying direction.

In the cooler inlet area 14 of the cooler 10, the bulk material is cooled in particular to a temperature of less than 1150 ° C.

The static grate preferably has passages through which cooling air enters the cooler 10 and the bulk material.

The cooling air is generated, for example, by at least one fan 18 arranged below the static grate, so that cooling air flows through the static grate from below.

Within the cooler 10, the bulk material to be cooled is moved in the conveying direction F.

The separation area 16 optionally adjoins the cooler inlet area 14 or directly to the cooler inlet 12, the cooler inlet area 14 optionally not being present or, for example, coinciding with the separation area 16.

The separation area 16 of the cooler 10 is optionally arranged in particular in such a way that the bulk material from the furnace outlet falls directly onto the static grate or the dynamic grate of the separation area 16.

In the exemplary embodiment in FIG. 1, the cooler inlet area follows

14 a separation area 16 of the cooler 10 in the flow direction of the bulk material.

In the separation area 16, the bulk material is separated into fine material and coarse material.

In the separation area 16, the bulk material is preferably cooled to a temperature of less than 1150 ° C, preferably 1100 ° C, in particular 800 ° C, the cooling being carried out in such a way that the liquid clinker phases present in the bulk material solidify completely into solid phases .

When leaving the separation area 16 of the cooler 10, the bulk material is preferably completely in the solid phase and at a maximum temperature of 1100 ° C.

When separating the bulk material into coarse material and fine material, at least the fine material is preferably at least partially or completely in the solid phase and has a temperature of less than 1150 ° C, in particular less than 1100 ° C.

At such a temperature there is no sticking or clumping of the bulk material.

The fine material particles and the coarse material particles are essentially separate from one another, preferably in different layers, so that a separation of the fine material and the coarse material can be carried out optimally without caking or clumping of the bulk material.

The separation area 16 of the cooler 10 has, for example, one or a plurality of fans 24, by means of which cooling air flows through the bulk material to be cooled. The bulk material in the separation area preferably has an upper area in which mostly or exclusively fine material is present, and a lower area in which mostly coarse material is present. Fine material is to be understood as bulk material with a grain size of about 105 mm to 4 mm, preferably 105 mm to 2 mm, the coarse material being bulk material with a grain size of 4 mm to 100 mm, preferably 2 mm to 100 mm. The separating cut between the coarse material and the fine material is preferably at a grain size of 2mm.

The separation area 16 is followed by a coarse material cooler 20 for cooling the coarse material separated from the fine material in the separation area 16 and a fine material cooler 22 for cooling the fine material separated from the coarse material in the separation area, the fine material cooler 22 and the coarse material cooler 20 being arranged parallel to one another . Preferably, mostly or exclusively fine material is passed from the separation area into the fine material cooler 22, with largely or exclusively coarse material being passed into the coarse material cooler 20. The fine material cooler 22 and / or the coarse material cooler 20 comprises, for example, a dynamic grate which has a mechanical conveyor unit with a plurality of conveyor elements movable in the conveying direction F and counter to the conveying direction F for transporting the bulk material in the conveying direction. The conveyor unit is, for example, a moving floor conveyor which has a plurality of conveyor elements for transporting the coarse material. In the case of a moving floor conveyor, the conveying elements are, for example, a plurality of planks, preferably grate planks, which form a ventilation floor. The conveying elements are arranged next to one another and can be moved in conveying direction F and against conveying direction F. The conveyor elements designed as conveyor planks or grate planks can preferably be traversed by cooling air, are arranged over the entire length of the coarse cooler 20 and form the surface on which the bulk material rests. The mechanical conveyor unit can also be a push conveyor, the mechanical conveyor unit through which cooling air can flow

Has aeration floor and a plurality of conveyor elements movable relative to the aeration floor. The conveying elements of the pusher conveyor are preferably arranged above the aeration base and have drivers running transversely to the conveying direction. The conveyor elements can be moved in the conveying direction F and counter to the conveying direction F for the transport of the bulk material along the aeration base. The conveying elements of the push conveyor and the moving floor conveyor can be moved according to the “walking floor principle”, the conveying elements all being moved simultaneously in the conveying direction and non-simultaneously against the conveying direction. Alternatively, other conveying principles from bulk material technology are also conceivable. Following the coarse material cooler 20, the cooled coarse material is discharged from the cooler 10 and preferably has a temperature of 50.degree. C. to 200.degree. C., preferably less than 100.degree. The coarse material cooler 20 has, for example, a plurality of fans 26, 28 below the ventilation floor, by means of which cooling air flows from below through the ventilation floor. The separation area 16 comprises, for example, a dynamic grate described above, which has a mechanical conveying unit with a plurality of conveying elements movable in the conveying direction and counter to the conveying direction F for transporting the bulk material in the conveying direction. It is also conceivable that the dynamic grate of the separation area 16 also forms the dynamic grate of the coarse material cooler 20 and extends over the entire length of the separation area 16 and the coarse material cooler 20.

The fines cooler 22 has a material inlet 30 for admitting fines from the separation area 16 of the cooler 10 into the fines cooler 22. The fines cooler 22 also has a material outlet 32 in an area of the fines cooler 22, for example opposite the material inlet 30, for discharging fines from the fines cooler 22. The separation area 16 has a fine material outlet 34 for discharging the fine material from the separation area 16 into the fine material cooler 22. The fine material outlet 34 and the material inlet 30 coincide, for example. The separation area

16 and the fines cooler 22 are connected to one another via material chutes, for example. For example, the fine material cooler 22 has a dynamic grate described above, which has a conveyor unit with a plurality of conveyor elements movable in the conveying direction and counter to the conveying direction F for transporting the bulk material in the conveying direction. The cooler 10 has, for example, a separation means 36 which is arranged in the separation area 16 of the cooler 10 and separates the fine material cooler 22 from the separation area 16 and the coarse material cooler 20. The separation means 36 is, for example, a wall which extends completely at least along one longitudinal side of the separation area 16 in the conveying direction F of the bulk material. For example, the separation means 36 also extends completely or at least partially in the conveying direction F along a longitudinal side of the coarse material cooler 20.

In the separation area 16, the bulk material is preferably already present in two phases, the fine material being arranged above the coarse material. The coarse material preferably rests on the dynamic grate of the separation area 16, the fine material resting on the coarse material. The separation means 36 is, for example, plate-shaped and extends from the dynamic grate of the separation area 16 in the vertical direction. The upper edge of the separating means 36 designed as a wall serves as an outlet for the fine material of the separation area 16 into the fines cooler 22. The fine material forming the upper region of the bulk material bed flows over the separating means 36 designed as a wall into the fine material cooler 22. The fine material outlet 34 is completely above the dynamic one Rust attached.

Optimally, mainly fine material reaches the fine material cooler, with a small proportion of coarse material in the fine material cooler also being desirable. The separation means 36 preferably has a height that is less than the height of the bulk material bed of the separation area 16. The fines outlet 34 is formed by the upper edge of the separation means 36 designed as a wall and is in particular arranged at a level below the height of the bulk material bed in the separation area 16 and does not extend, in particular at any point of the separation area 16, beyond the height of the bulk material bed. The wall preferably extends over the height of the coarse material portion of the

Bulk material bed out, wherein the fine material outlet 34 is arranged above the level of the coarse material portion of the bulk material bed. The separation means 36, preferably the wall, extends, for example, along the entire length of the fines cooler 22 in the conveying direction F on the fines cooler

22. The separation means 36 preferably extends over the entire longitudinal side of the fines cooler 22 and separates the fines cooler 22 from the separation area 16 and the coarse material cooler 20. The fines outlet 34 extends, for example, exclusively in the separation area 16, preferably along the length of the separation area 16. The Fine material cooler 22 is arranged, for example, parallel to the coarse material cooler 20 and extends, for example, over the entire length of the coarse material cooler 20 parallel to it. The fine material cooler 22, the separation area 16 and the coarse material cooler 20 each have, for example, a dynamic grate with a conveyor device. For example, a conveyor device of a dynamic grate working according to the "walking floor principle" is provided which comprises the fine material cooler 22, the separation area 16 and the coarse material cooler 20, the fine material cooler 22 being separated from the separation area 16 and the coarse material cooler 20 through the separation means 36, especially the wall, is separate.

FIG. 2 shows an exemplary embodiment of a fines cooler 22 with a mechanical conveying unit 42. A conveyor plank is shown by way of example in FIG. 2, which can be moved in conveying direction F and counter to conveying direction F. FIG. The mechanical conveyor unit 42 has cooling air inlets 60 through which cooling air passes from below into the bulk material lying on the mechanical conveyor unit 42. The bulk material in the fine material cooler 22 has coarse material 52 which is deposited on the mechanical conveyor unit 42, in particular on the conveyor planks, and forms the lower area of the bulk material. The bulk material in the fine material cooler 22 has fine material 54 which is deposited on the coarse material 52 and forms the upper region of the bulk material. The fine material 54 is raised, preferably fluidized, and moved in the conveying direction by the cooling air flowing into the fine material cooler 22. The fine material 54 behaves, for example, like a liquid mass and flows in the conveying direction F above the coarse material 52.

The fines cooler 22 optionally has the guide elements 58, shown with broken lines, for guiding the fines 54 within the fines cooler 22.

The guide elements 58 are, for example, plates made of metal or a heat-resistant material.

The guide elements 58 are, for example, evenly spaced from one another in the conveying direction F and each preferably extend over at least part or the entire width of the interior of the fines cooler.

The guide elements 58 are arranged, for example, parallel to one another.

The guide elements preferably extend into the bulk material, in particular into the upper region of the bulk material, which mainly consists of fine material 58.

The guide elements 54 are preferably not connected to the mechanical conveyor unit 42 and are attached at a distance from it.

The distance between the guide elements 58 and the mechanical conveyor unit 42 corresponds approximately to the height of the layer of coarse material within the bulk material, so that the guide elements 58 do not influence the flow of the coarse material 52 in the conveying direction F.

Alternatively, the guide elements 58 can also partially stand on the conveyor unit 42 and extend in the vertical direction.

As a result, the material flow in the fines cooler 22 is partially deflected and locally mixed in the process.

At the end of the fines cooler 22 on the material outlet side, there is arranged an inclined base 56 which, for example, has a wedge shape and opens into the material outlet 32.

The bottom 56 can also be designed to be flat, or alternatively it can also rise at an incline.

The coarse material 52 and the fine material 54 are preferably discharged together through the material outlet 32 from the fine material cooler 22.

The fine material cooler 22 furthermore has a housing 48 which, for example, also extends over the entire cooler 10, not shown in FIG. 2, with the coarse material cooler 20, the separation area 16 and the cooler inlet 14.

FIG. 3 shows a further exemplary embodiment of a fines cooler 22, the same elements being provided with the same reference numerals.

In contrast to FIG. 2, the fine material cooler 22 of FIG. 3 has a coarse material outlet 62 for discharging the coarse material 52 from the fine material cooler 22. The coarse material outlet 62 is designed, for example, as a sink so that the heavier coarse material settles in it when the fine material cooler 22 is in operation.

For example, the coarse material outlet 62 is arranged in front of the material outlet 32 in the conveying direction F.

A material lock, for example a rotary valve 64 for metering the coarse material 52 leaving the fine material cooler 22, adjoins the coarse material outlet.

In the exemplary embodiment of FIG. 3, the material outlet 32 forms a fine material outlet for discharging the fine material 54 from the fine material cooler 22. The base 56 at the fine material outlet can be designed to be flat or sloping.

FIG. 4 shows a further exemplary embodiment of a fines cooler 22, the same elements being provided with the same reference numerals.

The fine material cooler 22 shown in FIG. 4 has, for example, no mechanical conveying unit 42, but a pneumatic conveying unit 70 for conveying the coarse material 52.

The pneumatic delivery unit 70 comprises a plurality of compressed air devices 66 and a plurality of compressed air inlets 68. The fine material cooler 22 preferably has a ventilation base, in particular a grate, on which the bulk material rests.

The compressed air device 66 is, for example, a compressor for generating compressed air, each compressed air device 66 being connected to at least one compressed air inlet 68, so that compressed air is passed into the bulk material by means of the compressed air devices 66.

The compressed air inlets 68 are preferably formed in a ventilation base on which the bulk material rests within the fines cooler 22.

By way of example, a compressed air inlet 68 is formed in the housing 48.

The compressed air inlets 68 are preferably designed as channels for guiding the compressed air and point in particular in the conveying direction F, so that the bulk material is acted upon by the compressed air with a force pointing in the conveying direction F.

In particular, the compressed air inlets 68 are arranged in the area of the fine material cooler 22 in which mainly or exclusively coarse material is present when the fine material cooler 22 is in operation.

The compressed air devices 66 serve to transport the coarse material 52, which is deposited in the lower region of the bulk material, preferably on the aeration floor.

LIST OF REFERENCE NUMERALS 10 cooler 12 material inlet 14 cooler inlet area 16 separation area 18 fan 20 coarse material cooler 22 fine material cooler 24 fan 26 fan 28 fan 30 material inlet 32 material outlet 34 fine material outlet 36 separating means 38 fan 40 fan 42 mechanical conveying unit 48 housing 52 coarse material 54 fine material 56 fine material cooler outlet 58 guide elements 60 coarse air inlet 58 guide elements 60 coarse air inlet 64 rotary valve 66 compressed air device

Claims (15)

Claims 1. A method for cooling bulk material, in particular cement clinker, in a fine material cooler (22) comprising the steps: - Admitting bulk material to be cooled with a fine material content of 70% to 95%, in particular 75% to 85%, preferably 80% through a material inlet (30) into the fine material cooler (22), - conveying the bulk material to be cooled in the conveying direction (F) through the fine material cooler (22) to a material outlet (32). 2. The method according to claim 1, wherein the fine material of the bulk material is pneumatically conveyed. 3. The method according to any one of the preceding claims, wherein the bulk material has a coarse material content of 5% to 30%, in particular 25% to 15%, preferably 20% and the coarse material is conveyed pneumatically. 4. The method according to claim 3, wherein compressed air is fed into the fine material cooler (22) via compressed air inlets (66) pointing in the conveying direction (F) and the coarse material is transported in the conveying direction (F) by means of the compressed air. 5. The method according to claim 1 or 2, wherein the bulk material has a coarse material content of 5% to 30%, in particular 25% to 15%, preferably 20%, and wherein the coarse material is conveyed mechanically. 6. The method according to any one of the preceding claims, wherein the coarse material (52) and the fine material (54) are discharged separately from the fine material cooler (22). 7. The method according to any one of the preceding claims, wherein the bulk material is conveyed exclusively mechanically in a rear region of the fines cooler in the conveying direction (F). 8. Cooler (10) for cooling bulk material, in particular cement clinker, having a cooler inlet (12) for admitting bulk material to be cooled into the cooler (10) a separation area (16) arranged in the conveying direction (F) of the bulk material behind the cooler inlet (12) ) for separating coarse material and fine material, a coarse material cooler (20) connected to the separation area (16) for cooling the coarse material and a fine material cooler (22) connected to the separation area (16) and connected in parallel to the coarse material cooler (20) for cooling the Fine material, characterized in that the fine material cooler (22) has a first conveying unit for conveying coarse material and a second conveying unit for conveying fine material. 9. cooler (10) according to claim 8, wherein the first delivery unit is a mechanical or a pneumatic delivery unit. 10. Cooler (10) according to claim 8 or 9, wherein the second conveyor unit is a pneumatic conveyor unit. 11. Cooler (10) according to claim 9, wherein the mechanical conveying unit (42) has a plurality of conveying elements which can be moved simultaneously in the conveying direction (F) and non-simultaneously against the conveying direction (F). 12. Cooler (10) according to one of claims 9 to 11, wherein the pneumatic conveying unit for conveying the fine material (54) has a plurality of fans (38, 40) for subjecting the fine material to a flow of cooling air. 13. Cooler (10) according to claim 9, wherein the pneumatic conveying unit for conveying the coarse material in the conveying direction (F) has a compressed air device (66) for applying compressed air to the coarse material (52). 14. Cooler (10) according to one of claims 8 to 13, wherein a plurality of guide elements (58) for guiding the fines (54) within the fines cooler (22) are arranged in the fines cooler (22). 15. Cooler (10) according to one of claims 8 to 14, wherein the fine material cooler (22) has a coarse material outlet (62) for discharging coarse material (52) from the fine material cooler (22) and a fine material outlet (32) for discharging fine material (54) ) from the fines cooler (22).