BE1029343B1 - Co-current counter-current regenerative shaft kiln and method for firing carbonate rock - Google Patents

Abstract

The invention includes a method for firing material such as carbonate rocks in a cocurrent countercurrent regenerative shaft furnace (1) with two shafts (2) which are operated alternately as a combustion shaft and as a regenerative shaft and are connected to one another by means of a connecting duct (19). are, wherein the material flows through a material inlet (3) into a preheating zone (21) for preheating the material, a firing zone (20) for firing the material and a cooling zone (22) for cooling the material to a material outlet (40), wherein a cooling gas is admitted into the cooling zone, with exhaust gas being discharged from one of the ducts (2) via an exhaust gas outlet (6), the exhaust gas discharged from the duct (2) via the exhaust gas outlet (6) at least partially entering at least one of the ducts (2 ) is initiated. The invention also includes a cocurrent countercurrent regenerative shaft furnace (1) for burning and cooling material such as carbonate rocks, with two shafts (2) which can be operated alternately as a combustion shaft and as a regenerative shaft and are connected to one another by means of a connecting duct (19). , each shaft (2) having, in the flow direction of the material, a preheating zone (21) for preheating the material, a firing zone (20) for firing the material and a cooling zone (22) for cooling the material, each shaft (2) having an exhaust gas outlet (6) for discharging exhaust gas from the duct (2), wherein at least one exhaust gas outlet (6) is connected to a gas inlet (12, 15) for admitting gas into at least one duct (2).

Description

! BE2021/5326 Co-current counter-current regenerative shaft kiln and method for firing carbonate rock The invention relates to a co-current counter-current regenerative shaft kiln (PFR shaft kiln) and a method for firing and cooling material such as carbonate rocks with a PFR shaft kiln . The firing of carbonate rock in a PFR shaft kiln has been known for about 60 years. Such a PFR shaft furnace, known for example from WO 2011/072894 A1, has two vertical, parallel shafts that work cyclically, only one shaft, the respective combustion shaft, being burned while the other shaft works as a regenerative shaft. The combustion shaft is supplied with oxidizing gas in cocurrent with the material and fuel, with the resulting hot exhaust gases being conducted together with the heated cooling air supplied from below via the overflow channel into the exhaust shaft, where the exhaust gases are discharged upwards in countercurrent to the material and the preheat the material. The material is usually fed into the shaft from above together with the oxidizing gas, with fuel being injected into the combustion zone.

In each shaft, the material to be burned usually passes through a preheating zone for preheating the material, a subsequent firing zone in which the material is burned and a subsequent cooling zone in which cooling air is supplied to the hot material.

In order to meet the quality requirements for high reactivity of the burnt lime, as required in steel works, for example, the temperatures in the burning zone must not exceed 1100°C, preferably 1000°C. Furthermore, the demand for environmentally friendly production of quicklime is also increasing, so that certain requirements for the CO2 content of the exhaust gas for subsequent after-treatment must be met.

Proceeding from this, it is the object of the present invention to provide a PFR shaft furnace and a method for burning carbonate rock with a PFR shaft furnace

° BE2021/5326 to provide, with which lime with a high reactivity with simultaneous CO2 separation from the exhaust gas is made possible.

According to the invention, this object is achieved by a device having the features of independent method claim 1 and by a method having the features of independent device claim 10 . Advantageous developments result from the dependent claims. According to a first aspect, the invention comprises a method for burning and cooling material such as carbonate rocks in a cocurrent-countercurrent regenerative shaft furnace with two shafts, which are operated alternately as a combustion shaft and as a regenerative shaft and are connected to one another by means of a connecting duct. The material flows in the PFR shaft furnace through a material inlet into a preheating zone for preheating the material, a firing zone for firing the material and a cooling zone for cooling the material to a material outlet, with a cooling gas being admitted into the cooling zone. The exhaust gas is discharged from one of the ducts via an exhaust gas outlet, wherein the exhaust gas discharged from the duct via the exhaust gas outlet is at least partially introduced into at least one of the ducts. The exhaust gas is introduced, for example, directly into one of the shafts or indirectly via the connecting duct. The material to be burned is preferably limestone or dolomite with a grain size of 10 to 200 mm, preferably 15 to 120 mm, most preferably 30 to 100 mm. The cooling gas is air, for example. The cocurrent countercurrent regenerative shaft furnace has at least two shafts which are preferably arranged parallel to one another and vertically. The shafts can be operated alternately as a combustion shaft and as a regenerative shaft, each shaft having, in the direction of flow of the material, a preheating zone for preheating the material, a firing zone for burning the material and a cooling zone for cooling the material. Each shaft preferably has a material inlet for admitting material to be burned into the shaft, the material inlet being located in particular at the upper end of the respective shaft,

> BE2021/5326 so that the material falls into the respective chute by gravity. The material inlet and/or the material outlet is/are designed in particular as a lock for letting in and/or letting out material into the shaft furnace. A material inlet designed as a lock is preferably designed in such a way that only the raw material to be burned gets into the shaft, but not the ambient air. The material lock also prevents gas escaping from the shaft via the material inlet. The lock is preferably designed in such a way that it seals the shaft airtight against the environment and allows solids, such as the material to be burned, to enter the shaft.

The connecting duct is designed to connect the two shafts in terms of gas technology and preferably connects the combustion zones of the shafts to one another. When the PFR shaft furnace is in operation, one of the shafts is operated as a combustion shaft and is active, with the respective other shaft being operated as a regenerative shaft and being passive. In particular, the PFR shaft furnace is operated cyclically, with the function of the shafts being swapped after the end of the cycle time. This process is repeated continuously. In the active shaft operated as a combustion shaft, fuel is introduced into the combustion zone via the burner lances. The material to be burned is preferably heated to a temperature of about 700°C in the preheating zone of the burn shaft. In the shaft operated as a combustion shaft, the combustion zone is designed as a direct current combustion zone, with the material to be burned flowing parallel to the gas. The gas flows inside the combustion shaft from the preheating zone into the combustion zone and then via the connecting duct into the combustion zone and the preheating zone of the regenerative shaft. In the shaft operated as a regenerative shaft, the gas flows in the preheating zone and the combustion zone in countercurrent to the material to be burned. Both in the combustion shaft and in the regenerative shaft, cooling gas is passed through the cooling zone in countercurrent to the material to be cooled and is preferably completely discharged from the shaft via the cooling gas outlet of the cooling air extraction device, so that preferably no cooling gas flows from the cooling zone into the combustion zone.

* BE2021/5326 Each stack preferably has at least one flue gas outlet, for example at the top of the stack within the preheating zone.

The exhaust gas outlet is preferably arranged above the material column in a material-free area of the preheating zone.

The exhaust gas is preferably discharged exclusively from one shaft, in particular the regenerative shaft.

The discharged exhaust gas is preferably fed to the respective other shaft, in particular the combustion shaft, and/or to the regenerative shaft via the connecting duct.

Preferably, only part of the exhaust gas discharged from the regenerative shaft is fed back to at least one shaft.

A portion of the exhaust gas discharged from the regenerative shaft is discharged, for example, from the PFR shaft furnace and, for example, fed to further treatment, such as sequestration.

The exhaust preferably consists of CO, and optionally H2O. A fuel is preferably fed to the combustion zone and/or the preheating zone of the shaft operated as a combustion shaft via a fuel line.

The fuel is preferably fed to burner lances which are arranged in the combustion zone and/or the preheating zone.

The fuel is, for example, a fuel gas such as blast furnace gas or natural gas or pulverized coal or biomass or liquid fuels.

In the firing zone, the material is preferably heated to a temperature of about 1100°C.

Each shaft preferably has a plurality of burner lances which extend at least partially through the preheating zone and in particular open into the combustion zone of the respective shaft and for conducting, for example, fuel and/or an oxidizing gas such as air or air enriched with oxygen or pure oxygen. to serve.

Recirculation of the exhaust gas into at least one shaft enables lime to be produced with a high level of reactivity, while at the same time process gas with a CO2 content of more than 90%, based on dry gas, is produced.

With such a process waste gas, it is possible to liquefy and sequester it with less effort.

For example, the liquefied process waste gas is fed to further process steps or stored.

Alternatively, with the PGR shaft furnace described above, exhaust gas with less CO2 content, for example

> BE2021/5326 45% for the production of soda or 35% for the production of sugar or 30% for the production of precipitated calcium carbonate.

According to a first embodiment, the exhaust gas is introduced into the preheating zone of the shaft operated as a burning shaft.

Each shaft preferably has a gas inlet, in particular a combustion gas inlet, which is arranged in the upper region of the shaft in the preheating zone and is used for the inlet of the gas required for combustion.

The gas inlet is preferably arranged above the material column in a material-free space of the preheating zone.

The combustion gas inlet is preferably preceded by a control element, such as a flap or a quantity-adjustable compressor, via which the quantity of exhaust gas and/or oxidizing agent in the shaft can be adjusted.

The exhaust gas discharged from the shaft via the exhaust gas outlet preferably has a temperature of approximately 60°C-160°C, in particular 100°C.

Preferably, only part of the exhaust gas is introduced into the preheating zone of the combustion shaft.

Returning the exhaust gases to the preheating zone offers the possibility of increasing the amount of gas in the shaft, while at the same time ensuring a high concentration of CO2 in the exhaust gas.

According to a further embodiment, the exhaust gas is introduced into the connecting duct and/or into the combustion zone of the shaft operated as a regenerative shaft.

The connecting channel is preferably designed as a material-free space in which gas from the combustion shaft flows to the regenerative shaft.

Introducing the exhaust gas into the connecting duct enables the exhaust gas to be evenly mixed with the gases of the combustion zone of the combustion shaft, since no material is present in the connecting duct.

Preferably, only part of the exhaust gas is introduced into the connecting duct and/or into the combustion zone of the regenerative shaft.

According to a further embodiment, the exhaust gas is heated to a temperature of 900° C. to 1100° C., preferably 1000° C., before being introduced into the shaft, in particular into the connecting duct or into the combustion zone of the shaft operated as a regenerative shaft.

The exhaust gas is preferably heated in two steps, with heating to about 600° C. taking place in a first step and heating to about 1000° C. taking place in a further step.

The steps take place

° BE2021/5326 for example in separate devices such as an electric heater or heat exchanger.

The heat exchanger is, for example, a heat exchanger designed as a regenerator or a heat exchanger designed as a recuperator. The recuperator is, for example, a countercurrent recuperator, with the exhaust gas being heated in countercurrent to a fluid, such as the cooling gas drawn off via the cooling gas extraction device. The recuperator is, for example, a plate heat exchanger or a tube bundle heat exchanger.

A heat exchanger designed as a regenerator is preferably operated cyclically. The heat exchanger comprises, for example, two regenerators which are connected in parallel to one another and are each connected to the exhaust pipe and the cooling gas discharge pipe via a respective valve. The withdrawn cooling gas flows through exactly one of the regenerators in order to heat the regenerator. The exhaust gas to be heated flows through the other regenerator. After a certain time, in particular when switching the shafts between combustion and regeneration mode, the modes of operation of the regenerators are switched so that the other regenerator is flowed through with the exhaust gas to be heated and the withdrawn cooling gas. The advantage of a regenerator compared to a recuperator, which is designed as a tube bundle heat exchanger, for example, is that the regenerator stores the heat in ceramic materials and therefore does not corrode or scale at high temperatures.

According to a further embodiment, the exhaust gas is heated by means of a heat exchanger and/or a heating device, in particular an electrical heating device, a solar device or a combustion reactor. For example, the exhaust gas is heated exclusively by a heat exchanger or a heater. It is also conceivable that the exhaust gas is heated in a first step by a heat exchanger to a temperature of, for example, approximately 600° C. and then to a temperature of approximately 1000° C. in a heating device.

The heating device is preferably designed for indirect heating or for direct heating, for example by means of an oxyfuel burner. the

The heating device includes, for example, an electric heating device, an electric flow heater, a solar device, a combustion reactor and/or a heat exchanger and can be operated in particular with renewable energy sources. The heating device is, for example, an electrically operated heating device. In particular, the heating device is operated using solar energy and preferably includes a solar receiver, in particular a photovoltaic system for generating electrical energy using solar energy. The heating device comprises, for example, a solar thermal system, for example a heat exchange fluid being heated by means of solar energy and being heated in a heat exchanger, preferably in countercurrent to the recirculated exhaust gas. For example, the heating device includes a solar receiver that heats the recirculated exhaust gas, in particular directly. For this purpose, the solar receiver comprises, for example, part of the exhaust gas outlet line. The heating device has, for example, a combustion reactor which is preferably designed for the combustion of renewable energy sources, such as wood, with oxygen preferably being supplied instead of air in order to avoid the entry of nitrogen. The heating device preferably comprises a heat exchanger for heating the exhaust gas in countercurrent to a heat transfer fluid. The heat transfer fluid is heated, for example, by means of solar energy and/or the combustion reactor.

According to a further embodiment, the cooling gas heated in the cooling zone is discharged from the cooling zone of the shaft via a cooling gas discharge device. In particular, the cooling gas admitted into the cooling zone is completely discharged from the respective shaft via the cooling gas discharge device. The cooling gas is preferably introduced into the cooling zone from below via a cooling gas inlet arranged in the lower region of the cooling zone. The cooling gas extraction device preferably has a cooling gas outlet for discharging the cooling gas from the shaft. In particular, the cooling gas outlet is connected to a cooling gas discharge line for guiding the discharged cooling gas.

According to a further embodiment, the cooling gas discharged from the cooling zone is fed to a heat exchanger for heating the exhaust gas. The exhaust gas drawn off via the exhaust gas outlet is preferably in countercurrent before being introduced into the connecting duct and/or the combustion zone of the regenerative shaft

, BE2021/5326 heated by the discharged refrigerant gas. The exhaust gas is preferably heated to a temperature of 400°C to 800°C, in particular 600°C, by means of the heat exchanger.

According to a further embodiment, an oxidizing agent is supplied to the shaft operated as a burning shaft. The oxidizing agent is, for example, pure oxygen or an oxygen-rich gas with an oxygen content of at least 70 to 95%, preferably 90%. The oxidizing agent is preferably introduced into the preheating zone of the combustion shaft together with the exhaust gas. It is also conceivable that the shaft in the preheating zone has a separate oxidizing agent inlet for letting the oxidizing agent into the shaft separately from the exhaust gas.

According to a further embodiment, the content of oxygen and/or CO: in the exhaust gas and/or the cooling gas is determined, with the amount of oxidizing agent supplied to the combustion shaft and/or the amount of cooling gas being let out of the cooling zone of the shaft via the cooling gas extraction device being regulated .

The PGR shaft furnace preferably has a gas analysis device for determining the oxygen and/or CO 2 content in the exhaust gas and/or cooling gas. The gas analysis device is arranged, for example, in the exhaust gas line, in particular downstream of the branch of the combustion gas line. A gas analysis device is optionally or additionally arranged in the cooling gas discharge line, in particular downstream of the heat exchanger and, for example, of the filter.

The gas analysis device is connected in particular to a control device for transmitting the determined oxygen and/or the CO 2 content of the exhaust gas and/or the cooling gas.

The oxidizing agent line preferably has a control element, such as a valve or a flap, via which the amount of oxidizing agent in the respective shaft can be adjusted. The control element is preferably connected to the control device, the control device being designed in particular in such a way that it

? BE2021/5326 regulates the amount of oxidizing agent in the shaft depending on the oxygen and/or CO content of the exhaust gas determined by means of the gas analysis device. The control device is preferably designed in such a way that it compares the oxygen and/or CO content determined by means of the gas analysis device with a respective predetermined limit value or limit range and, if the determined value deviates from the limit value or limit range, the quantity of oxidizing agent in increases or decreases the shaft.

The control is used in particular for complete combustion of the fuel, which is fed to the PFR shaft furnace via the fuel line. This prevents an undesirably high proportion of oxygen in the exhaust pipe. The CO2 content is also measured to check the desired CO2 content in the flue gas pipe.

The cooling gas discharge line preferably has a regulating element, such as a valve or a flap, via which the quantity of cooling gas to be discharged via the cooling gas discharge device can be adjusted. The control element is preferably connected to the control device, with the control device being designed in particular in such a way that it regulates the quantity of cooling gas discharged via the cooling gas extraction device as a function of the oxygen and/or the CO2 content of the cooling gas determined by the gas analysis device. The control device is preferably designed in such a way that it compares the oxygen and/or CO content determined by means of the gas analysis device with a respective predetermined limit value or limit range and, if the determined value deviates from the limit value or limit range, the quantity via the cooling gas extraction device cooling gas to be discharged increased or decreased.

The control is used in particular to draw off the cooling gas as completely as possible from the PFR shaft furnace while at the same time having as little CO as possible, or preferably no CO, in the cooling gas discharge line.

The invention also includes a co-current countercurrent regenerative shaft kiln for firing and cooling material such as carbonate rocks. Those relating to the process of burning material such as carbonate rocks in a co-current

The embodiments and advantages described in the countercurrent regenerative shaft furnace also apply to the PFR shaft furnace in accordance with the device. The PGR shaft furnace comprises two shafts that are operated alternately as a combustion shaft and as a regenerative shaft and are connected to one another by means of a connecting duct. Each well has, in the flow direction of the material, a preheating zone for preheating the material, a firing zone for firing the material, and a cooling zone for cooling the material. Each stack further includes a flue gas outlet for discharging flue gas from the stack. The at least one exhaust gas outlet is connected to a gas inlet for admitting gas into at least one duct. The PFR shaft furnace preferably has a plurality of gas inlets for admitting exhaust gas drawn off from at least one of the shafts.

According to one embodiment, the gas inlet is arranged in the preheating zone of the shaft operated as a combustion shaft. The gas inlet in the preheating zone of the combustion shaft is preferably a combustion gas inlet, via which an oxidizing agent is preferably introduced into the preheating zone in addition to the exhaust gas. The gas inlet is preferably located at the top of the preheating zone.

According to a further embodiment, the gas inlet is arranged in the connecting duct for gas-technical connection of the combustion zones of the shafts and/or in the combustion zone of the shaft, in particular the regenerative shaft, and/or in a material-free space in the shaft. In particular, the material-free space is designed as an external annular space, which extends circumferentially around preferably the upper region of the cooling zone adjoining the combustion zone.

According to a further embodiment, between the exhaust gas outlet and the gas inlet in the connecting duct for the gas-technical connection of the combustion zones of the shafts and/or in the combustion zone is a heat exchanger and/or a heating device, in particular an electric heating device, a solar device or a combustion reactor, for heating the exhaust gas arranged. For example, the heat exchanger is arranged in front of the heating device in the flow direction of the exhaust gas. It is also conceivable that there is only one heat exchanger or one heating device for heating the exhaust gas.

According to a further embodiment, the cooling zone has a cooling gas inlet for letting cooling gas into the cooling zone and a cooling gas discharge device for discharging cooling gas from the shaft.

According to a further embodiment, the cooling gas extraction device has a material-free space within the cooling zone of the shaft. In particular, the material-free space is designed as an external annular space, which extends circumferentially around preferably the upper region of the cooling zone adjacent to the combustion zone. In particular, the cooling gas outlet is arranged in the material-free annular space.

The material-free space of the cooling gas extraction device is designed, for example, as an inner cylinder, which extends in particular centrally and in the vertical direction through the cooling zone. In particular, the inner cylinder extends at least partially into the combustion zone. The cooling gas outlet for discharging the cooling gas from the shaft is arranged in the inner cylinder. The inner cylinder preferably has a cooling gas inlet for letting in cooling gas of the cooling zones into the interior of the inner cylinder, wherein the cooling gas inlet is preferably arranged above the cooling gas outlet in the inner cylinder. In particular, the cooling gas inlet is arranged at the upper end of the cooling zone, so that the cooling gas preferably flows through the entire cooling gas zone and then into the inner cylinder of the cooling gas discharge device. Within the inner cylinder, the cooling gas preferably flows downwardly towards the cooling gas outlet and into the cooling gas discharge line. A cooling gas extraction device designed as an inner cylinder enables a low overall height of the cooling zone and comparatively simple conversion of known PFR shaft furnaces. The material-free space of the cooling gas extraction device is designed, for example, as a connecting duct for gas-technical connection of the cooling zones of the two shafts, with the cooling gas outlet preferably being arranged in the connecting duct, in particular centrally. The cooling gas extraction device is preferably designed in such a way that it discharges all of the cooling gas from the shaft, so that preferably no cooling gas enters the combustion zone or the connecting duct connecting the combustion zones of the shafts. In particular, the cooling gas extraction device is connected to a control element, such as a flap or a valve, for adjusting the amount of cooling gas to be extracted.

According to a further embodiment, the cooling gas extraction device is connected to a heat exchanger for heating the exhaust gas. The cooling gas extraction device is connected to the heat exchanger in particular by means of the cooling gas extraction line. The heat exchanger preferably serves to heat the exhaust gas that has been discharged from the preheating zone of the regenerative shaft via the exhaust gas outlet. The heat exchanger is connected in particular to the exhaust gas outlet and the cooling gas outlet of the cooling gas extraction device. According to a further embodiment, each shaft has a combustion gas inlet for admitting combustion gas into the preheating zone and/or the combustion zone, the combustion gas inlet being connected to an oxidizing agent line for conducting an oxidizing agent into the shaft. The combustion gas inlet is preferably connected to the exhaust gas outlet for directing the exhaust gas into the stack.

DESCRIPTION OF THE DRAWINGS The invention is explained in more detail below using several exemplary embodiments with reference to the attached figures. 1 shows a schematic representation of a PFR shaft furnace in a sectional view according to an exemplary embodiment.

FIG. 2a shows a schematic representation of a PFR shaft furnace in a sectional view according to a further exemplary embodiment. 2b to 2f show schematic representations of the PFR shaft furnace of FIG. 2a in cross-sectional views in the sectional planes marked in FIG. 2a. 3a shows a schematic representation of a PGR shaft furnace in a sectional view according to a further exemplary embodiment.

3b to 3e show schematic representations of the PFR shaft furnace of FIG. 3a in a longitudinal view and further cross-sectional views in the sectional planes marked in FIG. 3a.

4a-c shows a schematic representation of a PFR shaft furnace in a perspective view and two sectional views according to a further embodiment.

4d to 4h show schematic representations of the PFR shaft furnace of FIGS. 4a-c in a longitudinal view and further cross-sectional views in the sectional planes marked in FIGS. 4b and c.

FIG. 5 shows a schematic illustration of a PGR shaft furnace in a sectional view according to a further exemplary embodiment.

1 shows a PFR shaft furnace 1 with two parallel and vertically aligned shafts 2. The shafts 2 of the PFR shaft furnace 1 are constructed essentially identically, so that in FIG. 1 only one of the two shafts 2 is provided with reference symbols and in the following for the sake of simplicity, only one of the two shafts 2 is described. Each shaft 2 has a material inlet 3 for admitting material to be burned into the respective shaft 2 of the PFR shaft furnace 1. The material to be burned is in particular limestone and/or dolomite, preferably with a grain size of 10 to 200 mm, preferably from 15 to 120mm, most preferably from 30 to 100mm. The material inlets 3 are arranged, for example, at the upper end of the respective chute 2 so that the material falls through the material inlet 3 into the chute 2 due to the force of gravity. The material inlet 3 is designed, for example, as an upper opening of the shaft 2 and in particular as a lock 3 and preferably extends over all or part of the cross section of the shaft 2. A material inlet designed as a lock 3 is preferably designed in such a way that only the raw material to be burned gets into shaft 2, but not the ambient air. The lock 3 is preferably designed in such a way that it seals the shaft 2 airtight against the environment and allows solids, such as the material to be burned, to enter the shaft.

Each duct 2 further has a combustion gas inlet 12 at its upper end for admitting combustion gas for burning fuels. The combustion gas is, for example, dust-free exhaust gas from at least one of the shafts 2, the exhaust gas preferably being enriched with oxygen. Furthermore, each shaft 2 has an exhaust gas outlet 6 for discharging exhaust gases from the respective shaft 2 . Each exhaust gas outlet 6 and combustion gas inlet 12 is assigned a control element, for example. The amount of combustion gas in the respective combustion gas inlet 12 and the amount of exhaust gas to be drawn off via the respective exhaust gas outlet 6 can preferably be adjusted via the control elements, such as a volume-adjustable compressor 35 . The combustion gas inlet 12 and the exhaust gas outlet are arranged, for example, at the same level and in particular within the preheating zone 21 of the respective shaft 2 .

A material outlet 40 for discharging the burned material is arranged at the lower end of the shaft 2 . The material outlet 40 is, for example, a lock as described with reference to the material inlet 3 . The burned material is fed, for example, into an outlet funnel 25 which is followed by the material outlet 40 of the shaft 2 . The outlet funnel 25 is embodied in the form of a funnel, for example. The outlet funnel 25 preferably has a cooling gas inlet 23 for letting in cooling gas into the respective shaft 2 . The cooling gas is preferably fed into the cooling gas inlet by means of a compressor 33 .

During operation of the PFR shaft furnace 1, the material to be burned flows from top to bottom through the respective shaft 2, with the cooling air flowing from bottom to top, in countercurrent to the material, through the respective shaft 2. The furnace exhaust gas is discharged from the shaft 2 through the exhaust gas outlet 6 .

Below the material inlet 3 and the combustion gas inlet 12 is the preheating zone 21 of the respective shaft 2 in the flow direction of the material. In the preheating zone 21, the material and the combustion gas are preferably preheated to about 700°C. The respective shaft 2 is preferably filled with material to be burned. The material is preferably fed into the respective shaft 2 above the preheating zone 21 . At least part of the preheating zone 21 and the part of the respective shaft 2 adjoining it in the flow direction of the material are surrounded, for example, with a refractory lining.

A plurality of burner lances 10 are optionally arranged in the preheating zone 21 and each serve as an inlet for fuel, such as a fuel gas, oil or ground solid fuel. The PFR shaft furnace 1 has, for example, a cooling device for cooling the burner lances 10 . The cooling device comprises, for example, a plurality of cooling air ring lines which extend in a ring shape around the shaft area in which the burner lances 10 are arranged. Cooling air for cooling the burner lances 10 preferably flows through the cooling air ring lines. The burner lances 10 are preferably cooled by means of the exhaust gas discharged via the exhaust gas outlet 6 . The exhaust gas outlet 6 is preferably connected to the burner lances 10 for conducting exhaust gas to the burner lances 10 .

A plurality, for example twelve or more, burner lances 10 are preferably arranged in each shaft 2 at a substantially uniform distance from one another. The burner lances 10 have, for example, an L-shape and preferably extend in the horizontal direction into the respective shaft 2 and inside the shaft 2 in the vertical direction, in particular in the flow direction of the material. The ends of the burner lances 10 of a shaft 2 are preferably all arranged at the same level. The level at which the lance ends are arranged is preferably the lower end of the respective preheating zone 21. The burner lances 10 are preferably provided with a fuel line 9 for conducting

Fuel connected to the burner lances 10. The fuel line 9 is designed, for example, at least partially as a ring line, which extends circumferentially around the respective shaft 2 . Each shaft 2 preferably has a fuel line which is assigned to the burner lances 10 of the shaft 2 and which in particular has a control element for adjusting the fuel quantity to the burner lances 10 . The combustion zone 20 adjoins the preheating zone 21 in the flow direction of the material. In the combustion zone 20, the fuel is burned and the preheated material is fired at a temperature of about 1000°C. The PGR shaft furnace 1 also has a connecting channel 19 for connecting the two shafts 2 to one another in terms of gas technology. In particular, there is no material to be burned in the connecting channel 19 .

1 shows an example of a PFR lime kiln 1 with round shaft cross sections. However, the shaft cross-section can have a different geometric contour, such as round, semi-round, oval, square or polygonal. The combustion zone 20 extends, for example, in a first and a second shaft section, the first shaft section having a cross section which is essentially constant or which becomes slightly larger towards the bottom. The first shaft section is adjoined in the flow direction of the material by a second shaft section, which has a shaft cross-section that decreases in the flow direction of the material. The lower area of the first shaft section extends into the upper area of the second shaft section, so that an annular channel 18 is formed between the two shaft sections. The ring channel 18 forms a material-free space in which no material to be burned is arranged. In its upper area, the second shaft section has a larger cross section than the first shaft section, the cross section of the second shaft section being reduced to the cross section of the first shaft section in the flow direction of the material and preferably forming the lower end of the combustion zone 20 . The ring channel 18 preferably extends circumferentially around the lower area of the first shaft section of the combustion zone 20. The shafts 2 in FIG.

A cooling zone 22 , which extends to the material outlet 40 , adjoins the combustion zone 20 in the flow direction of the material in each shaft 2 .

The cooling zone is formed in a shaft section with a substantially constant or downwardly decreasing cross-section.

The cross section of the shaft section of the cooling zone 22 is larger than the cross section of the lower area of the burning zone 20, so that at the upper end of the cooling zone 22 and adjacent to the burning zone 20 another material-free space 17, in particular an annular shoulder, is formed in which no material is arranged.

The material is cooled within the cooling zone 22 to about 100°C in countercurrent to the cooling gas flowing through the material.

A preferably conical flow device is arranged at the lower end of the cooling zone 22 and serves to direct the material in the direction of the shaft wall.

Each cooling zone 22 has a cooling air outlet device 17 each with a cooling gas outlet 29 .

In the exemplary embodiment in FIG. 1 , the cooling air outlet device 17 is designed as a material-free, in particular ring-shaped, space 17 .

The cooling gas outlet 29 is preferably arranged in the shaft wall of the material-free space 17 at the upper end of the cooling zone 22 .

The cooling gas flowing into the cooling zone 22 via the cooling gas inlet 23 preferably flows completely out of the cooling gas outlet 29 of the cooling air outlet device 17 from the respective shaft 2 .

A discharge device 41 is preferably arranged at the end of each shaft 2 on the material outlet side.

The discharge devices 41 comprise, for example, horizontal plates, preferably a discharge table, which allow the material to pass through laterally between the discharge table and the housing wall of the PFR shaft furnace.

The discharge device 41 is preferably designed as a pusher or rotary table or as a table with a pusher scraper.

This enables a uniform throughput rate of the material to be burned through the shafts 2. The discharge device 41 also includes, for example, the outlet funnel 25, which is connected to the discharge table and at the lower end of which the material outlet 40 is attached.

When the PFR shaft furnace 1 is in operation, one of the shafts 2 is active in each case, with the respective other shaft 2 being passive.

The active pit 2 is referred to as the burn pit and the passive pit 2 is referred to as the regenerative pit. The PFR shaft furnace 1 is in particular operated cyclically, with a typical number of cycles being, for example, 75 to 150 cycles per day. After the cycle time has expired, the function of shaft 2 is swapped. This process is repeated continuously. Material such as limestone or dolomite is alternately fed into the shafts 2 via the material inlets 3 . In the active shaft 2 operated as a combustion shaft, a fuel is introduced into the combustion shaft 2 via the burner lances 10 . The material to be burned is heated to a temperature of about 700° C. in the preheating zone 21 of the burning shaft. In the exemplary embodiment of FIG. 1, the left-hand shaft 2 is operated as a burning shaft, with the right-hand shaft 2 being operated as a regenerative shaft.

During operation of the PFR shaft furnace 1, the cooling gas flows in the combustion shaft 2 as well as in the regenerative shaft 2 in countercurrent to the material to be cooled through the cooling zone 22 and is preferably completely discharged from the shaft 2 via the cooling gas outlet 29, so that preferably no cooling gas flows from the cooling zone 22 into the burning zone 20.

Within the shaft 2 operated as a combustion shaft, the combustion gas flows through the combustion gas inlet 12 into the combustion shaft and in cocurrent with the material within the combustion zone 20 into the material-free space designed as an annular channel 18 . From the material-free space 18, the gas flows via the connecting duct 19 into shaft 2, which is operated as a regenerative shaft Preheating zone 21 and leaves the regenerative shaft through the exhaust gas outlet 6 of the regenerative shaft. Preferably, the exhaust gas discharged from the shaft 2 has a temperature of 60°C to 160°C, preferably 100°C.

The exhaust gas is conducted into an exhaust gas line 39 which is connected to the exhaust gas outlet 6 . The exhaust pipe 39 optionally has an exhaust gas filter 31 for filtering fine particles, in particular dust, from the exhaust gas downstream of the exhaust gas outlet 6 in the flow direction of the exhaust gas. Downstream of the exhaust filter 31, the exhaust line 39 has a branch, with a portion of the exhaust gas in a

Combustion gas line 4 is routed to the combustion gas inlet 12 . Downstream of the branch, the combustion gas line 4 has, in the direction of flow of the exhaust gas, a control element, such as a throttle valve, and a compressor 35, for example. The combustion gas line 4 is preferably connected to the combustion gas inlets 12 of the shafts 2, with the exhaust gas preferably being supplied only to the combustion gas inlet 12 of the shaft 2 operated as a combustion shaft via a control element connected upstream of the combustion gas inlet 12. The combustion gas line 4 is preferably connected to an oxidizing agent line 14 so that an oxidizing agent, preferably pure oxygen, is introduced into the combustion gas line 4 and then into the shaft 2 via the combustion gas inlet 12 together with the exhaust gas. It is also conceivable that an oxygen-rich gas with an oxygen content of at least 70 to 95%, preferably 90%, is introduced into the combustion gas line 4 as the oxidizing agent.

The part of the exhaust gas that is not returned to the combustion gas inlet 12 is fed in the exhaust pipe 39 to a gas inlet 15 in the connection duct 19 . Downstream of the branch of the combustion gas line 4 in the direction of flow of the exhaust gas, the exhaust pipe 39 preferably has a volume-adjustable compressor 36, a heat exchanger 43 and optionally a heating device 8 for heating the exhaust gas. The heat exchanger 43 is designed as a recuperator, for example, with the exhaust gas being heated in countercurrent to the cooling gas drawn off and the cooling gas being cooled at the same time. The heat exchanger 43 is connected in particular via a cooling gas discharge line 11 to the cooling gas outlets 29 of both shafts 2, so that the exhaust gas in the heat exchanger 43 is preferably heated in countercurrent by means of the cooling gas discharged. Following the heat exchanger, the cooling gas discharge line 11 optionally has a regulating element for adjusting the quantity of cooling gas to be drawn off and a filter 16 for removing dust from the cooling gas. The exhaust gas is preferably heated to a temperature of approximately 900° C. to 1100° C., in particular 1000° C., in the heat exchanger 43 and/or the heating device 8 . It is also conceivable that the exhaust pipe 39 only has a heat exchanger 43 or a heating device 8 for heating the exhaust gas. For example, the exhaust gas is heated to a temperature of approximately 600° C. in the heat exchanger 43 and then to a temperature of approximately 1000° C. in the heating device 8 .

The heating device 8 is, for example, an electrically operated heating device. In particular, the heating device is operated using solar energy. It is also conceivable that the heating device 8 comprises a heat exchanger, with the heating medium flowing in countercurrent being heated by solar energy. The heating device 8 is preferably designed as a combustion reactor for burning preferably renewable energy sources such as wood, with the combustion preferably taking place in such a way that the combustion gas has a high CO2 content of at least 90%.

A portion of the exhaust gas is branched off upstream of the heat exchanger 43 and discharged via a cooling device 32 by means of a compressor 37 . The entire amount of CO2 from the calcination and the incineration, as well as the water from the incineration, is preferably removed from the PFR shaft furnace 1 . The cooling device 32 is, for example, a heat exchanger, which is preferably operated with a coolant, such as water, in countercurrent. The exhaust gas line has, for example, a compressor 34, 36 before and after the branching off of the exhaust gas to be discharged.

The connecting duct 19 has a gas inlet 15 for admitting recirculated exhaust gas into the connecting duct 19 . The gas inlet 15 is connected to the exhaust gas outlet 6 of the shaft 2 via the exhaust gas line 39 , so that exhaust gas discharged from the shaft 2 , dedusted and heated is conducted into the connecting duct 19 . The gas inlet 15 is arranged, for example, centrally in the upper wall of the gas channel 15 . It is also conceivable that the gas inlet 15 is arranged at a different position in the wall of the connecting channel 19 or in the ring channels 18 . It is also conceivable that a plurality of gas inlets 15 are fitted in the connecting duct 19 or in the ring ducts 18 which are each connected to the exhaust pipe 39 .

1 also shows two gas analysis devices 45, 46 by way of example. The gas analysis devices 45, 46 are designed in such a way that they determine the oxygen and/or the CO 2 content of the respective gas. A gas analysis device 45 is arranged, for example, in the exhaust gas line 39 downstream of the branch of the combustion gas line 4 and for determining the oxygen and/or the

CO, content of the exhaust gas formed. The gas analysis device 45 is connected in particular to a control device (not shown) for transmitting the determined oxygen and/or CO2 content of the exhaust gas.

The oxidizing agent line 14 preferably has a control element, such as a valve or a flap, via which the amount of oxidizing agent in the combustion gas line 4 can be adjusted. The control element is preferably connected to the control device, with the control device being designed in particular in such a way that it regulates the quantity of oxidizing agent in the combustion gas line 4 depending on the oxygen and/or CO2 content of the exhaust gas determined by the gas analysis device 45.

The control is used in particular for complete combustion of the fuel that is supplied to the PFR shaft furnace 1 via the fuel line 9 . An undesirably high proportion of oxygen in the exhaust pipe 39 is thus prevented. To check the desired CO: content in the exhaust pipe 39, the CO: content is also measured.

The control device is preferably designed in such a way that it compares the oxygen and/or CO content determined by means of the gas analysis device 45 with a respective predetermined limit value or limit range and, if the determined value deviates from the limit value or limit range, the quantity of oxidizing agent increased or decreased in the flue gas line.

The amount of oxidizing agent is preferably increased if the oxygen content falls below the limit value or limit range. Preferably, the amount of oxidant is reduced when the threshold or range of the determined oxygen content is exceeded.

A gas analysis device 46 is arranged, for example, in the cooling gas discharge line 11, in particular downstream of the heat exchanger 43 and, for example, the filter 16 and is designed to determine the oxygen and/or the CO 2 content of the discharged cooling gas. The gas analysis device 46 is connected in particular to the control device (not shown) for transmitting the determined oxygen and/or the CO 2 content of the cooling gas.

The cooling gas discharge line 11 preferably has a control element, such as a valve or a flap, via which the quantity of cooling gas to be discharged via the cooling gas discharge device 17 can be adjusted.

The control element is preferably connected to the control device, with the control device being designed in particular in such a way that it regulates the quantity of cooling gas discharged via the cooling gas extraction device 17 as a function of the oxygen and/or the CO2 content of the cooling gas determined by means of the gas analysis device 46.

The control is used in particular to ensure that the cooling gas is drawn off as completely as possible from the PFR shaft furnace 1 while at the same time having as little or preferably no CO in the cooling gas discharge line 11. The control device is preferably designed in such a way that the oxygen and/or oxygen content determined by means of the gas analysis device 46 or compares the CO 2 content with a respective predetermined limit value or limit range and, if the determined value deviates from the limit value or limit range, the quantity of cooling gas to be discharged via the cooling gas extraction device 17 is increased or reduced.

The quantity of cooling gas is preferably increased if the determined CO 2 content falls below the limit value or limit range.

Preferably, the amount of cooling gas is reduced when the limit or range of the determined CO 2 content is exceeded.

FIG. 2a shows a further exemplary embodiment of a PFR shaft furnace, this largely corresponding to the PGR shaft furnace of FIG.

The same elements are provided with the same reference symbols.

In the PFR shaft furnace 1 of FIG. 2a, the shaft 2 on the left is operated as a combustion shaft, for example.

In contrast to the PGR shaft furnace of FIG. 1, the PGR shaft furnace 1 of FIG

Cooling zone 22 extends at least partially into combustion zone 20 and has a cooling gas outlet 29 connected to cooling gas discharge line 11 . 2b to 2f show cross-sectional views of the PFR shaft furnace 1 in the sectional planes marked in FIG. 2a.

The cooling zone 22 is formed, for example, in a shaft section which has an approximately constant cross section, the shaft cross section of the cooling zone 22 corresponding to the shaft cross section of the lower area of the combustion zone 20 . The material-free annular space of the PFR shaft furnace of FIG. 1 is therefore not formed in the exemplary embodiment of FIG. 2a. Each shaft 2 of the PFR shaft furnace 1 of FIG. 2a has an inner cylinder 29 which extends centrally through the cooling zone 22 in the vertical direction. For example, the inner cylinder 29 extends from the discharge device 41 through the cooling zone 22 into the combustion zone 20 up to the height of the connecting duct 19. To cool the inner cylinder 29, a plurality of cooling air ducts are formed in its outer walls, which are connected to a cooling air line 7 for conducting cooling air are connected. The cooling air is preferably conducted by means of a compressor 38 via the cooling air line 7 into the cooling air ducts of the inner cylinder 26 . The heated cooling air is routed into the cooling gas discharge line 11, for example, and is preferably routed into the heat exchanger 43 for heating the exhaust gas. The inner cylinders 26 each have a cooling air inlet 27 extending radially outwards and a cooling air outlet 28 which are connected to the cooling air line 7 . Fig. 2f shows a cross-sectional view on the section plane E-E drawn in Fig. 2 through the cooling air inlets 27 and cooling air outlets 28 of the inner cylinder 26.

The inner cylinder 26 of the cooling gas extraction device 17 has a cooling gas outlet 29 which extends radially outwards from the inner cylinder 26 through the shaft wall and serves to conduct cooling gas from the inner cylinder into the cooling gas extraction line 11 . FIG. 2e shows a cross-sectional view through the cooling gas outlet 29 on the cutting plane D-D drawn in FIG. 2a. The cooling gas inlet 30 extends through the inner cylinder wall into the cooling zone 22 and connects the interior of the inner cylinder 26 with the cooling zone 22. Fig. 2d shows a cross-sectional view on the section plane C-C drawn in Fig. 2a through the cooling gas inlet 30. By way of example, each

Inner cylinder 26 has four cooling gas inlets 30, each of which is formed at the same height in the inner cylinder wall and preferably extends outwardly in a star shape into the cooling zone 22 at a uniform distance from one another.

The cooling gas inlet 30 is preferably arranged above the cooling gas outlet 29 in the cooling zone 22 .

During operation of the PFR shaft furnace 1, the cooling gas flows from bottom to top through the cooling zone 22 and into the cooling gas inlet 30 into the inner cylinder 26 of the cooling gas extraction device 17. Preferably, all of the cooling gas introduced into the cooling zone 22 flows through the cooling gas inlets 30 into the cooling gas extraction device 17, so that no cooling gas enters the combustion zone 20.

The cooling air outlet 29 of the inner cylinder 26 is preferably arranged in the lower area of the cooling zone 22 .

The cooling gas flows in particular from the cooling gas inlet 30 in the inner cylinder 26 downwards to the cooling gas outlet 29. The routing of the cooling gas drawn off from the cooling zone 22 and the exhaust gas drawn off from the preheating zone 21 correspond in the exemplary embodiment in Fig. 2a to that referred to in Fig. 1 described interconnection.

3a and b show a further embodiment of a PGR shaft furnace, this largely corresponding to the PGR shaft furnace of FIGS.

The same elements are provided with the same reference symbols.

In the PFR shaft furnace 1 of FIG. 3, the shaft 2 on the left is operated as a combustion shaft, for example.

In contrast to the PGR shaft furnace of FIGS. 1 and 2, the PGR shaft furnace 1 of FIG.

The further connection channel 24 is arranged below the connection channel 19 for the gas connection of the combustion zones 20 of the two shafts 2 .

In particular, the further connecting channel 24 is arranged at the upper end of the cooling zone 22, preferably directly below the combustion zone 20.

The cooling gas outlet 29 for discharging the cooling gas, in particular completely, from the two shafts 2 into the cooling gas discharge line 11 is in the further connecting channel 24 .

Fig. 3b shows a longitudinal sectional view of the PFR shaft furnace of Fig. 3a at the sectional plane D-D shown in Fig. 3a.

3c to 3e show further cross-sectional views of the PFR shaft furnace 1 of FIG. 3a at the sectional planes indicated in FIG. 3a.

By way of example, the shafts 2 of the exemplary embodiment in FIGS. 3a to e have a rectangular cross section.

The cooling gas outlet 29 extends, for example, over the entire width of the cross section of the shaft 2 and out of the shaft wall.

In the exemplary embodiment of FIG. 3, the line of the cooling gas drawn off from the cooling zone 22 and the exhaust gas drawn off from the preheating zone 21 correspond to the connection described with reference to FIG.

4a-h shows a further exemplary embodiment of a PFR shaft furnace, this largely corresponding to the PGR shaft furnace of FIG.

The same elements are provided with the same reference symbols.

In contrast to the PGR shaft furnace of FIG. 3, the PGR shaft furnace 1 of FIGS. 4a-c has a cooling gas extraction device 17 which comprises two connecting channels 42a,b.

The connecting channels 42a,b are arranged parallel to one another and each extend to opposite outer sides of the shafts 2. The cooling zones 22 of the two shafts 2 are gas-connected to one another via two connecting channels 42a,b.

Each connecting channel 42a,b has in particular a respective cooling gas outlet 29, which is connected to a cooling gas discharge line 11, not shown in FIGS. 4a-c.

FIG. 4d shows a sectional view of a connecting channel 42b at the sectional plane drawn in FIG. 4c.

The cooling gas outlet 29 is, for example, formed centrally between the two shafts, preferably at the narrowest point of the connecting channel 42b.

In particular, the connecting channels 42a,b are identical.

The cross section, in particular the height, of the connecting channels 42 increases in the direction of the shafts, in particular downwards into the respective shaft 2, and decreases between the two shafts 2. The width of the connecting channels 42a,b is constant, for example.

4e to h show cross-sectional views of the PFR shaft furnace 1 at the sectional planes shown in FIG. 4c.

By way of example, in the exemplary embodiment in FIGS. 4a to h, the combustion zones 20 of the shafts 2 are also connected via two parallel connecting channels 19a, b arranged on opposite sides of the shafts 2 on the outside.

The connecting channels 194a, b and/or 42ab for connecting the combustion zones 20 and the cooling zones 22 can optionally be arranged circumferentially around the two shafts 2.

The line of the cooling gas drawn off from the cooling zone 22 and the waste gas drawn off from the preheating zone 21 correspond in the exemplary embodiment of FIG. 4 to the connection described with reference to FIG.

FIG. 5 shows a further exemplary embodiment of a PFR shaft furnace 1, this largely corresponding to the PGR shaft furnace of FIG. The same elements are provided with the same reference symbols. In contrast to the exemplary embodiment in FIG. 1, the PFR shaft furnace 1 in FIG. 5 is provided with a heat exchanger 43 designed as a regenerator 44 . The heat exchanger 43 has, for example, two regenerators 44 which are connected in parallel to one another. The regenerators 44 are each connected to the exhaust gas line 39 and the cooling gas discharge line 11 via a respective valve, in particular a shut-off valve. During operation of the PGR shaft furnace, the withdrawn cooling gas flows through exactly one of the regenerators 44 in order to heat the regenerator 44 . The exhaust gas to be heated flows through the respective other regenerator 44 . After a certain time, in particular when switching the shafts between combustion and regeneration mode, the modes of operation of the regenerators are switched so that the exhaust gas to be heated and the cooling gas drawn off flows through the other regenerator. The regenerator 44, heated by means of the withdrawn cooling gas, then gives off the heat to the exhaust gas. The lime produced with the previously described PFR shaft furnace 1 of FIGS. 1 to 4 has a high reactivity, while at the same time process gas with a CO2 content of more than 90% based on dry gas is produced. With such a process waste gas, it is possible to liquefy and sequester it with little effort. For example, the liquefied process waste gas is fed to further process steps or stored. Alternatively, waste gas with a lower CO2 content, for example 45% for soda production or 35% for sugar production or 30% for the production of precipitated calcium carbonate, can also be generated with the PFR shaft furnace described above.

LIST OF REFERENCE NUMERALS 1 PGR shaft furnace 2 shaft 3 material inlet/lock

4 Combustion gas line 6 Exhaust outlet 7 Cooling air line 8 Heating device 9 Fuel line

10 Burner lances 11 Coolant gas discharge line 12 Combustion gas inlet 14 Oxidizer line Gas inlet

15 16 filter 17 material-free space / cooling gas extraction device 18 annular duct / material-free space 19 connecting duct combustion zone

20 21 preheating zone 22 cooling zone 23 cooling gas inlet 24 further connecting channel of the cooling zones outlet funnel

25 26 inner cylinder 27 cooling air inlet 28 cooling air outlet 29 cooling gas outlet cooling gas inlet

30 31 Exhaust gas filter 32 Cooling device 33 - 38 Compressor 39 Exhaust pipe 40 Material outlet / lock

41 discharge device 42a,b connecting channels 43 heat exchanger/recuperator 44 regenerator 45,46 gas analysis device

Claims (17)

patent claims 1. A method for firing material such as carbonate rocks in a co-current countercurrent regenerative shaft furnace (1) with two shafts (2) which are operated alternately as a combustion shaft and as a regenerative shaft and are connected to one another by means of a connecting duct (19), wherein the material flows through a material inlet (3) into a preheating zone (21) for preheating the material, a firing zone (20) for firing the material and a cooling zone (22) for cooling the material to a material outlet (40), with a cooling gas into the cooling zone, exhaust gas being discharged from one of the ducts (2) via an exhaust gas outlet (6), and characterized in that the exhaust gas discharged from the duct (2) via the exhaust gas outlet (6) is at least partially discharged into at least one of the ducts (2) is initiated. 2. The method according to claim 1, wherein the exhaust gas is introduced into the preheating zone (21) of the shaft (2) operated as a burning shaft. 3. The method according to any one of the preceding claims, wherein the exhaust gas is introduced into the connecting duct (19) and/or into the combustion zone (20) of the shaft (2) operated as a regenerative shaft. 4. The method according to claim 3, wherein the exhaust gas is heated before being introduced into the connecting duct (19) or into the combustion zone (20) of the shaft (2) operated as a regenerative shaft, in particular to a temperature of 900°C to 1100°C, preferably 1000 °C, is heated. 5. The method according to claim 4, wherein the exhaust gas by means of a heat exchanger (43) and / or a heating device (8), in particular an electric Heating device, a solar device or a combustion reactor, is heated. 6. The method according to any one of the preceding claims, wherein the cooling gas heated in the cooling zone (22) is discharged from the cooling zone (22) of the shaft (2) via a cooling gas discharge device (17). 7. The method according to claim 5, wherein the cooling gas discharged from the cooling zone (22) is fed to a heat exchanger (43) for heating the exhaust gas. 8. The method according to any one of the preceding claims, wherein the shaft operated as a combustion shaft, an oxidizing agent is supplied. 9. The method according to any one of the preceding claims 6 or 8, wherein the content of oxygen and / or CO in the exhaust gas and / or the cooling gas is determined and wherein the amount of oxidizing agent supplied to the combustion shaft and / or the amount of via the cooling gas extraction device (17) cooling gas discharged from the cooling zone (22) of the stack (2). 10. Cocurrent countercurrent regenerative shaft furnace (1) for burning and cooling material such as carbonate rocks, with two shafts (2) which can be operated alternately as a combustion shaft and as a regenerative shaft and are connected to one another by means of a connecting duct (2), each Shaft (2) in the flow direction of the material has a preheating zone (21) for preheating the material, a burning zone (20) for burning the material and a cooling zone (22) for cooling the material, each shaft (2) having an exhaust gas outlet (6) for discharging exhaust gas from the shaft (2), characterized in that at least one exhaust gas outlet (6) is connected to a gas inlet (12, 15) for admitting gas into at least one shaft (2). 11. Direct current countercurrent regenerative shaft furnace (1) according to claim 10, wherein the gas inlet (12) is arranged in the preheating zone (21) of the shaft (2) operated as a combustion shaft. 12. Direct current countercurrent regenerative shaft furnace (1) according to claim 10 or 11, wherein the gas inlet (15) in the connecting channel (19) and/or the combustion zone (20) of the shaft (2) and/or a material-free space in the shaft (2) is arranged. 13. Cocurrent countercurrent regenerative shaft furnace (1) according to any one of claims 10 to 12, wherein between the exhaust gas outlet (6) and the gas inlet (15) in the connecting channel (19) and / or the combustion zone (20) a heat exchanger ( 43) and/or a heating device (8), in particular an electrical heating device, a solar device or a combustion reactor, is arranged for heating the exhaust gas. 14. Cocurrent countercurrent regenerative shaft furnace (1) according to any one of claims 10 to 13, wherein the cooling zone (22) has a cooling gas inlet (23) for admitting cooling gas into the cooling zone (22) and a cooling gas discharge device (17) for discharging Has cooling gas from the shaft (2). 15. DC-countercurrent regenerative shaft furnace (1) according to claim 14, wherein the cooling gas discharge device (17) is connected to a heat exchanger (43) for heating the exhaust gas. 16. Cocurrent countercurrent regenerative shaft furnace (1) according to claim 14 or 15, wherein the cooling gas discharge device (17) comprises a material-free space within the cooling zone (22). 17. Cocurrent countercurrent regenerative shaft furnace (1) according to any one of claims 10 to 16, wherein each shaft (2) has a combustion gas inlet (12) for admitting combustion gas into the preheating zone (21) and/or the combustion zone (20). and wherein the combustion gas inlet (12) with a Oxidant line (14) for conducting an oxidant into the shaft (2).