BE1028091B1 - Device and method for burning and / or calcining lumpy goods - Google Patents

Abstract

The present invention relates to a shaft furnace (10) for burning carbonate-containing material in particular with a shaft (12) having a material inlet (22) in the direction of flow of the material, at least one burning zone (26) for burning the material with at least one fuel line (14, 16) ) for admitting fuel into the combustion zone (26), a cooling zone (28) with a cooling air inlet (36) for cooling the fired material, and a material outlet (30) for discharging the material from the shaft furnace (10), the shaft furnace ( 10) has an exhaust gas discharge line (24) for discharging exhaust gas from the shaft (12), and wherein the shaft furnace (10) has a cooling gas discharge device (38) for discharging cooling air from the shaft (12) which extends from the cooling zone (28 ) extends into the combustion zone (26) and from the combustion zone (26) out of the shaft (12).

Description

Device and method for burning and / or calcining lumpy goods The invention relates to a device and method for burning and / or calcining lumpy goods, in particular limestone or other carbonates, with a furnace having at least one burning zone and one cooling zone.

From CH 378 217 A, a shaft furnace for the continuous firing of mineral materials with a firing zone and a cooling zone is known, the hot gases of the firing zone and the cooling air for the material being removed via a suction space formed in the transition area between the firing and cooling zones.

DE 27 22 719 A1 describes a PFR furnace with two similar shafts each having a combustion zone and a cooling zone, each shaft having an annular channel in the area between the combustion zone and cooling zone, which are connected to one another via an overflow channel.

From EP 2 230 223 A1 a method and a device for the production of lime is known in which the exhaust gas is supposed to produce as pure, sequesterable carbon dioxide as possible.

Here the material is first fed to a furnace chamber and burned there with fuel and a gas with an oxygen content of over 90% by volume.

The calcined product is then cooled in a cooling zone with a cooling gas.

A lock arrangement is provided between the furnace and the cooling zone in order to separate the atmospheres of the two treatment rooms.

In this way it can be ensured that no cooling gas, which is usually formed by air, gets into the furnace.

In the furnace, the fuel can therefore essentially be burned with pure oxygen, so that a very carbon dioxide-rich exhaust gas is produced, which can be further concentrated through recirculation.

The lock arrangement provided between the furnace and the cooling zone must on the one hand ensure a gas-tight seal between the two process rooms and on the other hand withstand the very hot, fired material.

The lock arrangements suitable for this task are, however, relatively complex and expensive and require a large overall height.

From DE 10 2010 060 866 B3 a lime kiln is known which has a combustion zone, the lower end of which protrudes into the cooling zone of the shaft. With this design, a maximum throughput of only 250t / d is possible. In the lime industry, however, lime shaft kilns with a throughput of around 400 to 600 t / d are currently required. It is therefore the object of the present invention to provide a space-saving device and a method for burning and / or calcining lumpy material with a firing shaft and a cooling shaft, so that the atmospheres in the firing shaft and in the cooling shaft can be set in a targeted manner in a simple and inexpensive manner. At the same time, a high material throughput of at least 400t / d should be possible in the lime kiln.

According to the invention, this object is achieved by a device with the features of the independent device claim 1 and by a method with the features of the independent method claim 9. Advantageous developments result from the dependent claims.

A shaft furnace for burning carbonate-containing material in particular comprises, according to a first aspect, a shaft having a material inlet in the direction of flow of the material, at least one combustion zone for burning the material with at least one fuel line for admitting fuel into the combustion zone, a cooling zone with a cooling air inlet for cooling the fired material, and a material outlet for discharging the material from the shaft furnace. The shaft furnace has an exhaust gas discharge line for discharging exhaust gas from the shaft. Furthermore, the shaft furnace comprises a cooling gas extraction device for discharging cooling air from the shaft, which air extends from the cooling zone into the combustion zone and from the combustion zone out of the shaft.

The material to be burned is, for example, a granular material, in particular limestone, with a grain size of 10 to 150 mm, preferably 30 to 100 mm, in particular 40 to 80 mm.

The material inlet is arranged in particular at the upper end of the shaft. A preheating zone for preheating the material is preferably arranged upstream of the combustion zone in the direction of flow of the material. The preheating zone is preferably directly connected to a material inlet of the material into the shaft furnace and is used to preheat the material to a temperature of approximately 600.degree. C. to 800.degree. The firing zone is preferably directly connected to the preheating zone and is used for firing the material, which is preferably heated to a temperature of about 950.degree. C. to 1800.degree. The cooling zone preferably adjoins the firing zone and is used to cool the fired material to a temperature of 100 ° C., for example. The material outlet is arranged, for example, in an outlet funnel adjoining the cooling zone, the material outlet having, for example, a turntable or a sliding table for discharging material from the cooling zone into the outlet funnel.

The fuel line preferably comprises a plurality of burner lances, which extend through the shaft wall into the combustion zone and, in particular, are tubular and serve to guide fuel into the combustion zone.

The exhaust gas discharge line is preferably arranged in the upper region of the shaft, in particular in the preheating zone or in the upper region of the combustion zone.

The shaft furnace preferably has an oxidizing agent line for conducting oxidizing agent into the combustion zone. The oxidizing agent is, for example, pure oxygen, air, air enriched with oxygen or a gas with an oxygen content of at least 90%. The oxidizing agent line has, for example, an oxidizing agent lance which extends into the combustion zone of the shaft furnace and has an outlet for discharging oxidizing agent into the combustion zone. The oxidizing agent lance is preferably attached to the burner lance or directly below the burner lance. It is also conceivable that the oxidizing agent lance runs through the burner lance. The burner lance is preferably designed in such a way that oxidizing agent flows through the burner lance together with combustion air and fuel.

The inlet of the cooling gas extraction device for admitting cooling air into the cooling gas extraction device is preferably arranged completely within the cooling zone. In particular, the inlet is arranged below the fuel lines, in particular the mouths of the burner lances in the combustion zone. The cooling gas extraction device is preferably arranged at least partially below the exhaust gas extraction line. The outlet of the cooling gas discharge device for discharging the gas into a cooling gas discharge line arranged outside the shaft is preferably arranged within the combustion zone or the preheating zone.

The special design and arrangement of the cooling air extraction device enables the cooling gas extraction to be influenced in a simple manner. The atmosphere in the combustion zone is essentially only separated from the atmosphere in the cooling zone by the material located in the lowest part of the combustion zone. The cooling gas introduced into the combustion zone with overpressure basically takes the path of least resistance. The amount of gas to be withdrawn can be controlled very easily by the regulating element, which is arranged, for example, in the cooling gas discharge line and is regulated as a flap or valve, so that, for example, all of the cooling gas is withdrawn via the cooling gas discharge device and does not reach the combustion zone via the bulk material. Of course, by means of a suitable position of the control element, it is also possible that only a partial amount of the cooling gas is drawn off via the cooling gas extraction device and the remainder is fed to the cooling zone. Finally, it is basically also conceivable that the regulating element is opened so far that part of the exhaust gas is drawn off from the combustion zone through the bulk material into the cooling zone and from there via the cooling gas extraction device.

According to a first embodiment, the cooling gas extraction device extends centrally through the combustion zone.

This enables uniform burning of the material present in the burning zone without the cooling gas extraction device negatively influencing the burning process.

The cooling gas extraction device preferably extends over the entire length of the combustion zone.

The cooling gas extraction device is, for example, a pipe or a shaft with an in particular circular or angular cross section.

According to a further embodiment, the combustion zone is at least partially circular and is arranged concentrically with the cooling gas extraction device.

The width of the circular ring is, for example, about 0.5 m to 2 m, preferably 1 m.

For example, the combustion zone is designed completely or partially as a hollow cylinder, the interior of the hollow cylinder being formed by the cooling gas extraction device.

The cooling gas extraction device is preferably closed off, so that the cooling gas extraction device forms a material-free space when the shaft furnace is in operation.

According to a further embodiment, the cooling gas extraction device is connected to a control element for regulating the amount of gas which flows through the cooling gas extraction device.

The regulating element is, for example, a valve or a flap.

This enables a specific amount of cooling exhaust air to be discharged through the cooling gas extraction device, in which case, for example, the cooling air can be extracted completely or partially from the cooling zone.

When the cooling air is partially extracted from the cooling zone by the cooling gas extraction device, the remaining part of the cooling air flows into the combustion zone and is discharged from the shaft via the exhaust gas extraction line.

According to a further embodiment, the control element is connected to a sensor which is designed and set up to determine the pressure difference between the combustion zone and the cooling air extraction device.

The shaft furnace preferably has a further sensor for determining the oxygen content and / or the CO2 content in the exhaust gas discharge line and / or the cooling gas discharge line.

According to a further embodiment, the regulating element is connected via a control device to the sensor for determining the pressure difference and / or the oxygen content and / or the CO2 content.

The control device is designed in such a way that it controls the regulating element as a function of the determined or desired pressure difference, the oxygen content and / or the CO2 content.

The control element can preferably be moved from an open position, in which the cooling gas discharge line is hardly or not at all narrowed by the control element, into a closed position, in which no gas can flow through the cooling gas discharge line.

The control device controls the movement of the regulating member, preferably steplessly between the closed and the open position.

The sensors are preferably connected to the control device in such a way that the determined pressure difference, oxygen content and CO2 content are transmitted to the control device.

According to a further embodiment, the cooling gas extraction device is connected to a cooling air extraction line for guiding the cooling exhaust air discharged from the shaft and wherein the cooling air extraction line has a heat exchanger, a filter for dedusting the cooling exhaust air and / or the control element in the flow direction of the cooling exhaust air.

The heat exchanger is preferably operated with the exhaust air from the exhaust gas discharge line.

Furthermore, a cooling gas, such as air, is fed into the cooling air exhaust line, for example.

It is also conceivable not to pass the cooling exhaust air through a heat exchanger, but to use it, for example, to generate electricity, dry ground material or for heating purposes.

According to a further embodiment, the fuel line is connected to a plurality of burner lances which extend into the combustion zone and wherein the burner lances are arranged at at least two different height levels within the combustion zone.

The burner lances are preferably attached to the inner wall of the combustion zone and are evenly spaced from one another.

In particular, the burner lances are arranged at the lower end region of the burning zone.

The invention also comprises a method for firing, in particular carbonate-containing material, in a shaft furnace with a shaft, the material flowing through a material inlet into at least one burning zone for burning the material and a cooling zone for cooling the burned material to a material outlet. The cooling air is let into the cooling zone and the exhaust gas is discharged from the shaft via an exhaust gas discharge line. The cooling air is discharged from the shaft via a cooling air extraction device which extends from the cooling zone into the combustion zone and from the combustion zone out of the shaft. The advantages and embodiments described above with reference to the shaft furnace also apply in correspondence with the method to the method for burning material in a shaft furnace. According to one embodiment, the amount of gas that is withdrawn by the cooling gas extraction device is adjusted by a control element connected to the cooling gas extraction device.

The pressure difference between the cooling air extraction device and the combustion zone is determined according to a further embodiment and the amount of gas that is extracted by the cooling gas extraction device is regulated as a function of the determined pressure difference or a desired pressure difference.

According to a further embodiment, the oxygen content and / or the CO2 content of the gas withdrawn by the cooling gas extraction device and / or the exhaust gas withdrawn through the exhaust gas extraction line is determined and the amount of gas extracted by the cooling gas extraction device is determined as a function of the determined or desired oxygen content and / or the CO2 content is regulated. For example, to produce medium-hard and hard-burnt lime with reduced reactivity, the position of the control element is set in such a way that no exhaust gas from the combustion zone reaches the cooling air extraction device, in particular the cooling zone. All of the exhaust gas produced within the combustion zone is preferably discharged from the shaft via the exhaust gas discharge line. The regulating element is preferably set in such a way that neither exhaust gas from the combustion zone enters the cooling zone nor cooling air from the cooling zone into the combustion zone.

To produce soft-burnt lime with high reactivity, the position of the control element is preferably set such that part of the exhaust gas from the combustion zone flows into the cooling zone and is preferably discharged from the shaft via the cooling air extraction device. In this position of the regulating element, no cooling air preferably passes from the cooling zone into the combustion zone. A certain pressure difference, an oxygen content and / or a CO2 content is preferably set in the control device, the control device being designed such that it controls the regulating element so that the desired pressure difference, the oxygen content and / or the CO2 content is achieved. If the pressure inside the cooling air extraction device is too high, the control element is closed in order to achieve a pressure reduction.

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 representation of a device for burning and / or calcining lumpy material, in particular limestone, according to an exemplary embodiment.

FIG. 2 shows a schematic representation of a device for burning and / or calcining lumpy material, in particular limestone, according to a further exemplary embodiment.

1 shows a shaft furnace 10 for firing granular material, the shaft furnace 10 comprising a shaft 12 which preferably extends in the vertical direction and, for example, has a substantially constant cross section. For example, the shaft 12 has a round, in particular circular, or angular, in particular square, cross section. The shaft 12 is surrounded by a shaft wall which is made, for example, of steel with an adjoining brick, fireproof inner wall. At its upper end, the shaft 12 has a material inlet 22 which is designed, for example, as an upper opening of the shaft 12 and preferably extends over all or part of the cross section of the shaft 12. The material inlet 22 is used to let material to be burned into the shaft furnace

10. In an upper region, the shaft 12 has, in addition to the material feed 22 for supplying lumpy material, in particular limestone, an exhaust gas discharge line 24 for discharging furnace exhaust gas. The material to be burned is conveyed by gravity from top to bottom through the shaft 12, the shaft 12 having, in the conveying direction of the material, a burning zone 26 for burning the material and a cooling zone 28 for cooling the burned material. The shaft 12 preferably has a preheating zone in front of the burning zone 26 in the conveying direction, which extends from the material inlet 22 to the burning zone 26 and serves to preheat the material before burning. In a lower region of the combustion zone 26, fuel lines 14, 16 for introducing fuel and oxidizing agent feed lines 18, 20 for introducing an oxidizing agent into the combustion zone 26 of the shaft 12 are arranged. The fuel lines are shown schematically by arrows, these each representing, for example, a plurality of fuel lines. The oxidizing agent feed lines 18, 20 are each connected to both or only one fuel line 14, 16, for example, so that the oxidizing agent flows into the combustion zone 26 together with the fuel. The oxidizing agent feed lines 18, 20 are each connected, for example, to a fan, preferably a compressor, so that the oxidizing agent is acted upon by the oxidizing agent feed lines 18, 20 in the direction of the fuel lines 14, 16. Each oxidizing agent feed line 18, 20 is designed, for example, as a ring line that extends around the circumference of the shaft wall. The ring lines are arranged, for example, above the fuel lines 14, 16 and each connected to a plurality of burner lances of the fuel lines 14, 16. At least one of the oxidizing agent feed lines 18, 20 is used to convey air, air enriched with oxygen or pure oxygen, while another one of the oxidizing agent feed lines 18, 20 is used to convey shaft exhaust gases into the combustion zone 26. At least one of the oxidizing agent feed lines 18, 20 is connected to the exhaust gas discharge line 24, so that shaft exhaust gas is passed into the combustion zone 26. The oxidizing agent is, for example, air, pure oxygen, exhaust air from the shaft furnace or a gas with an oxygen content of around 90%. The fuel lines 14, 16 include, for example, a plurality of burner lances which extend through the shaft wall into the combustion zone 26.

For example, the burner lances of the fuel lines 14, 16 are arranged in two levels, the burner lances of the upper level optionally having a first insertion depth into the combustion zone 26 and the burner lances of the lower level having a second insertion depth into the combustion zone 26. Via the fuel lines 14, 16, gaseous, powdery or liquid fuel is preferably fed into the combustion zone 26 together with the oxidizing agent from the oxidizing agent feed line 18, 20.

A material outlet 30 for discharging the fired material is arranged at the lower end of the shaft 12. An outlet funnel 32 connects to the cooling zone 28 in the material conveying direction and opens into the material outlet 30 for discharging the material from the shaft furnace 10. In the outlet funnel 32, a discharge device 34 is arranged, for example, which serves to discharge material from the cooling zone 28 of the shaft furnace 10 into the outlet funnel 32. The discharge device 34 is, for example, a turntable or a pusher table. Below the material outlet 30 there is, for example, either a tightly closing material discharge flap or, if required, a tightly closing material lock. The material flows through the shaft furnace 10 essentially due to the force of gravity and is thermally treated in countercurrent or partially in cocurrent. The height of the shaft 12 is preferably determined by the dwell times of the fuel to be determined according to the method in connection with the setting of the conveying speed by means of the discharge device 34.

These dwell times are distributed over the upper preheating zone adjoining the material inlet 22, the burning zone 26 following downwards and the cooling zone 28 that runs up to the discharge device 34 ° C, with the burning zone 26 having a temperature of 800 ° C to 1800 ° C, for example, and in the cooling zone 28 the material is cooled down to approx. 100 ° C again. The shaft furnace 10 has one or more air inlets 36 for introducing air into the shaft furnace 10. For example, an air inlet 36 is arranged in the shaft furnace 10 in FIG. 1, which introduces air into the outlet funnel 32. The air is preferably blown into the outlet funnel 32 at a pressure of up to 500 mbar. The air is referred to below as secondary air or cooling air. The secondary air flows through the shaft furnace 10, in particular the shaft 12, from bottom to top in the vertical direction and in countercurrent to the material and leaves the shaft 12 through the exhaust gas discharge line 24 and / or through the cooling air discharge device 38 and the cooling air discharge line 54 furthermore a cooling air extraction device 38 for discharging at least part of the cooling air from the duct 12. The cooling air extraction device 38 extends, for example, centrally through the combustion zone 26 of the shaft 12. The combustion zone 26 of the shaft 12 is preferably designed at least partially or completely as an annular space which is arranged concentrically to the cooling air extraction device 38. Optionally, the cooling air extraction device 38 extends from the cooling zone 28 or the boundary between the combustion zone 26 and the cooling zone 28 through the combustion zone 26, for example, into the preheating zone and out of the shaft 12 through the shaft wall. The cooling air extraction device 38 is connected to a cooling air extraction line 54 for guiding the cooling air extracted from the shaft 12 by means of the cooling air extraction device 38.

The cooling air extraction device 38 preferably has a circular cross section and is closed at the top so that no material to be burned enters the cooling air extraction device 38. The burning zone 26 has, in particular, an annular cross-section, the width of the annular ring being approximately 0.5 to 2 m, preferably approximately 1 m. During operation, a column of material is formed in the combustion zone 26 of the shaft 12 with the material fed in via the material feed 22, the material moving downward under the force of gravity and being withdrawn in the area of the cooling zone 28 via the material outlet 30 as a calcined product, for example quicklime . The material fills the combustion zone 26 over the entire preferably circular cross-section and the cooling zone 28. The cooling air extraction device 38 is preferably free of material.

The cooling gas flows through the bulk material and reaches the cooling air extraction device 38. The cooling air extraction device 38 is connected via the cooling air extraction line 54 to a control element 40 in the form of, for example, a flap to regulate the amount of air flowing through the cooling air extraction line 54.

The exhaust gas discharge line 24 for removing the exhaust gas from the combustion zone 26 is preferably connected to a filter 42 for dedusting the exhaust gas and optionally to a cooling device 46 for cooling the hot exhaust gas. The exhaust gas from the combustion zone 26 is at least partially or completely discharged from the shaft 12 via the exhaust gas discharge line 24. The exhaust gas withdrawn from the shaft 12 via the exhaust gas discharge line 24 is dedusted in the filter 42 and then discharged as dedusted exhaust gas 44 for further processing. Optionally, cooling, in particular water cooling, can take place in a cooling device 46 behind the filter 42. The exhaust gas 44 discharged before or after the cooling device 46 has a high CO2 content and can, for example, be fed to sequestration and / or further industrial use, such as the production of soda or precipitated calcium carbonate.

For example, part of the exhaust gas discharged from the exhaust gas discharge line 24 is introduced into the combustion zone 26, for example in order to set the combustion temperature, and used as an oxidizing agent. The exhaust gas discharge line 24 is therefore optionally connected to one of the oxidizing agent feed lines 18, 20, so that exhaust gas flows into the oxidizing agent feed line. For example, part of the exhaust gas cooled by means of the cooling device 46 is fed to the combustion zone 26 together or separately with the oxidizing agent. A heat exchanger 48, for example, is arranged between the cooling device 46 and the oxidizing agent feed line 18, 20.

The recirculated part of the exhaust gas is preheated, for example, to 500 °, for example, in the heat exchanger 48 operated, for example, by the withdrawn cooling air. So that the heat transfer in the heat exchanger 48 is not reduced by deposits, it can be useful to cool the withdrawn cooling gas, which has a temperature of 900 ° C., for example, to below 700 ° C., preferably below 600 ° C., with the cooling can be done for example by mixing with air or in the cooling device 46. A fan 50 or compressor is preferably provided for accelerating the recirculated exhaust gas in the direction of the oxidizing agent feed line 18, 20.

The cooling air extraction line 54 is in particular connected to the heat exchanger 48 and, subsequently, optionally with a filter 52, so that the cooling air extracted via the cooling air extraction device 38 is cooled and dedusted. For further cooling of the withdrawn cooling air, a coolant, such as air, is optionally mixed with the withdrawn cooling air via the mixed air supply line 58, preferably before entering the heat exchanger 48. The heat exchanger 48, the filter 52 and the control element 40 are thus arranged one after the other in the cooling gas discharge line 54. It is also conceivable not to pass the cooling exhaust air through a heat exchanger, but to use it, for example, to generate electricity, dry ground material or for heating purposes.

The control element 40 is also connected to a control device, not shown in FIG. 1, which is connected to one or more sensors 56. The shaft furnace 10 has at least one sensor 56 which is designed and set up to measure the pressure difference between the combustion zone 26 and the cooling air extraction device 38. Furthermore, sensors for measuring the oxygen content and / or the CO2 content can be arranged in the cooling air discharge line 54 and / or exhaust gas discharge line 24.

The measured values provide information about the amount of the cooling gas supplied to the cooling zone 28 via the cooling air inlets 36 which is discharged via the cooling gas extraction device 38. The amount can be adjusted via the control element 40. The cooling gas will always choose the path of least resistance. For example, when the control element 40 is in a certain position, the cooling gas vent is set in such a way that the cooling gas neither flows into the combustion zone 26 nor the exhaust gas from the combustion zone 26 into the cooling zone 28. In this situation, a pressure difference of zero or close to zero would be established at the sensor 56. However, a corresponding check can also be carried out, for example, through the oxygen content and / or CO2 content of the discharged cooling gas or of the exhaust gas. If the regulating element 40 were to be adjusted in the sense of a further opening, part of the exhaust gas would gradually be diverted from the combustion zone 26 into the cooling zone 28 and from there via the cooling gas extraction device 38. Correspondingly, if the regulating member 40 is closed further, part of the cooling air will flow over into the combustion zone 26, so that only a part of the cooling gas will be drawn off via the cooling gas draw-off device 38.

The regulating member 40 formed by a shut-off flap thus enables a very simple, efficient and inexpensive way of influencing the cooling gas vent. Nevertheless, if desired, the two atmospheres in the combustion zone 26 and in the cooling zone 28 can be separated from one another without the need for an expensive lock arrangement.

The position of the control element 40 depends primarily on the desired application, in particular on the desired composition of the exhaust gas or the nature of the fired material. For example, in order to produce medium-hard and hard-burnt lime with reduced reactivity, the position of the control element is set in such a way that no exhaust gas from the combustion zone 26 enters the cooling air extraction device 38, in particular the cooling zone 28. All of the exhaust gas produced within the combustion zone is preferably discharged from the exhaust gas discharge line 24 from the shaft 12. Preferably that will

Control element 40 is set in such a way that neither exhaust gas from the combustion zone 26 into the cooling zone 28 nor cooling air from the cooling zone 28 into the combustion zone 26. To produce soft-burnt lime with high reactivity, the position of the control element is set in such a way that part of the exhaust gas from the combustion zone 26 flows into the cooling zone 28 and is preferably discharged from the shaft 12 via the cooling air extraction device 38. In this position of the regulating element 40, preferably no cooling air passes from the cooling zone 28 into the combustion zone 26.

For example, if one wants to obtain an exhaust gas with a high CO2 content of, for example 90% by volume, based on a dry exhaust gas, the regulating element 40 must ensure that no cooling gas gets into the combustion zone 26. In addition, one will preferably choose an oxidizing agent with a very high oxygen content of at least 90%, preferably more than 90% by volume. The resulting exhaust gas is particularly suitable for subsequent sequestration.

In the context of the invention, it is also conceivable that the shaft furnace 10 described above or the associated method is used to produce an exhaust gas which is required in the soda industry. For this purpose, the exhaust gas should have a CO2 content of around 40 to 42% and an oxygen content of less than 2%. In order to obtain such an exhaust gas, the control element must be set in such a way that only a portion of the cooling gas is withdrawn via the cooling gas discharge line, while the other part reaches the combustion shaft.

Another possible application is the production of precipitated calcium carbonate. The special construction of the device operated in excess pressure, with a material-free, gas-filled cooling air extraction device in the cooling and burning zone 26, 28 in combination with the control element, results in a shaft furnace 10 for burning and / or calcining of lumpy material, which is characterized by a particularly simple and inexpensive possibility of influencing the composition of the exhaust gas or the atmospheres in the combustion zone 26 and the cooling zone 28.

FIG. 2 shows a further embodiment of the shaft furnace 10, the structure largely corresponding to that in FIG. 1 and being provided with the same reference numerals.

In contrast to FIG. 1, FIG. 2 has no heat exchanger, filter and no connection to a mixed air supply line 58 in the cooling air discharge line 54.

The cooling air discharge line 38 has the regulating element 40, so that the cooling air drawn off via the cooling air discharge line 38 is directed to the regulating element 40.

In contrast to FIG. 1, the exhaust gas discharge line 24 does not have a heat exchanger for preheating the exhaust gas recirculated for introduction into the combustion zone 26.

In the exemplary embodiment in FIG. 2, preheating of the exhaust gas before it enters the combustion zone 26 is therefore advantageously dispensed with.

This is advantageous, for example, when the lowest possible firing temperature is desired in the firing zone 26, for example in order to produce lime with a high reactivity.

In this case, the heated cooling air is withdrawn via the cooling air extraction device 38 into the cooling air extraction line 54.

The withdrawn cooling air is used, for example, for downstream processes, such as the generation of electricity, drying of ground material or for heating purposes.

LIST OF REFERENCE NUMERALS 10 shaft furnace 12 shaft 14 fuel lines 16 fuel lines 18 oxidizing agent feed line 20 oxidizing agent feed line 22 material inlet 24 exhaust gas exhaust line 26 combustion zone 28 cooling zone 30 material outlet 32 outlet funnel 34 discharge device 36 cooling air inlets 38 cooling air exhaust device 40 regulating element 42 filter 44 dust-free exhaust gas 46 cooling device 48 heat exchanger 50 cooling air exhaust pipe 54 58 Mixed air supply line

Claims (12)

Claims 1. Shaft furnace (10) for burning in particular carbonate-containing material with a shaft (12) having a material inlet (22) in the direction of flow of the material, at least one burning zone (26) for burning the material with at least one fuel line (14, 16) for inlet of fuel into the combustion zone (26), a cooling zone (28) with a cooling air inlet (36) for cooling the fired material, and a material outlet (30) for discharging the material from the shaft furnace (10), the shaft furnace (10) being a Has exhaust gas discharge line (24) for discharging exhaust gas from the shaft (12), characterized in that the shaft furnace (10) has a cooling gas discharge device (38) for discharging cooling air from the shaft (12) which extends from the cooling zone (28) into the combustion zone (26) and from the combustion zone (26) out of the shaft (12). 2. Shaft furnace (10) according to claim 1, wherein the cooling gas extraction device (38) extends centrally through the combustion zone (26). 3. Shaft furnace (10) according to one of the preceding claims, wherein the combustion zone (26) is at least partially circular and is arranged concentrically with the cooling gas extraction device (38). 4. Shaft furnace (10) according to one of the preceding claims, wherein the cooling gas extraction device (38) is connected to a control element (40) for controlling the amount of gas which flows through the cooling gas extraction device (38). 5 shaft furnace (10) according to any one of the preceding claims, wherein the control element (40) is connected to a sensor (56) which is designed and set up to determine the pressure difference between the combustion zone (26) and the cooling air extraction device (38). 6. Shaft furnace (10) according to claim 5, wherein the control element (40) is connected to the sensor (56) via a control device and the control device is designed such that it controls the control element (40) as a function of the determined pressure difference. 7. Shaft furnace (10) according to one of the preceding claims, wherein the cooling gas exhaust device (38) is connected to a cooling air exhaust line (54) for guiding the cooling exhaust air discharged from the shaft (12) and wherein the cooling air exhaust line (54) is a heat exchanger in the flow direction of the cooling exhaust air (48), a filter (52) for removing dust from the cooling exhaust air and / or the control element (40). 8. Shaft furnace (10) according to one of the preceding claims, wherein the fuel line (14, 16) is connected to a plurality of burner lances which extend into the combustion zone (26) and wherein the burner lances are at at least two different height levels within the combustion zone ( 26) are arranged. 9. A method for burning in particular carbonate-containing material in a shaft furnace (10) with a shaft (12), the material through a material inlet (22) into at least one burning zone (26) for burning the material and a cooling zone (28) for cooling of the fired material flows to a material outlet (30), with cooling air being admitted into the cooling zone (28) and with the exhaust gas being discharged from the shaft (12) via an exhaust gas discharge line (24) and characterized in that the cooling air is discharged via a cooling air extraction device ( 38) is discharged from the shaft (12), which extends from the cooling zone (28) into the combustion zone (26) and from the combustion zone (26) out of the shaft (12). 10. The method according to claim 9, wherein the amount of gas that is withdrawn by the cooling gas extraction device (38) is adjusted by a control element (40) connected to the cooling gas extraction device (38). 11. The method according to claim 9 or 10, wherein the pressure difference between the cooling air extraction device (38) and the combustion zone (26) is determined and the amount of gas that is withdrawn by the cooling gas extraction device (38) depending on the determined or a desired pressure difference is regulated. 12. The method according to any one of claims 9 to 11, wherein the oxygen content and / or the CO2 content of the gas withdrawn by the cooling gas extraction device (38) and / or of the exhaust gas withdrawn through the exhaust gas extraction line (24) is determined and the amount of gas, which is withdrawn by the cooling gas extraction device (38) is regulated as a function of the determined or desired oxygen content and / or the CO2 content.