BE1030238B1 - entrained flow calciner - Google Patents

Abstract

The present invention relates to an entrained flow calciner 1 with a first combustion chamber 10, the first combustion chamber 10 having a first combustion device 12, the entrained flow calciner 1 having a material feed 14 into the first combustion chamber 10, characterized in that the entrained flow calciner 1 has a second combustion chamber 20 , wherein the second combustion chamber 20 is arranged below the first combustion chamber 10, wherein the second combustion chamber 20 has a second combustion device 22, wherein between the first combustion chamber 10 and the second combustion chamber 20 a constriction 30 is arranged.

Description

'BE2022/5067

entrained flow calciner

The invention relates to a flow calciner which enables a particularly targeted adjustment of the temperature of the initial reaction of the mineral to be thermally treated

material possible.

On the one hand, when material orders fluctuate, there is the problem of precisely adjusting the temperature at the material entry point into the calciner. Since the gas flow cannot be changed proportionally to the material application to maintain the flow conditions, it may be difficult to provide the energy necessary for the reaction (via the

fuel and setting the correct temperature).

Furthermore, there is an interest in carrying out a short initial treatment step at a very high temperature during thermal treatment. This can be useful, for example, to remove the outermost layer of mineral particles

Material to melt, which has an influence on the product properties

has reactivity.

The object of the invention is to create an entrained flow calculator in which a particularly controlled temperature setting is possible. Another focus here is to achieve a high temperature when the material enters the cacinator without the material falling through a formed flame.

This task is solved by an entrained flow calciner with the features specified in claim 1 and the method specified in claim 10

characteristics. Advantageous further developments result from the subclaims, the following description and the drawings.

The entrained flow calciner according to the invention has a first combustion chamber. The

Combustion chamber usually has an enlarged diameter compared to the rest of the entrained flow calciner. The first combustion chamber has a first

Burning device on. The first combustion device serves to generate the thermal energy for the thermal treatment of a mineral substance, for example lime or

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Lithium ore, to provide. This can be achieved, for example, by supplying natural gas and combustion with the air flowing in from below. The

Entrained flow calciner has a material feed into the first combustion chamber. About the

The material to be thermally treated is fed in, usually a mineral material

Material, for example lime or lithium ore, is supplied.

According to the invention, the entrained flow calciner additionally has a second combustion chamber. The second combustion chamber is arranged below the first combustion chamber. The second

Combustion chamber has a second combustion device. It is essential that a constriction is arranged between the first combustion chamber and the second combustion chamber.

The effect of this arrangement is that the gas stream entering from below is first heated in the second combustion chamber and can thus be brought to a desired temperature at which the gas stream then enters from the second combustion chamber through the constriction into the first combustion chamber. The second combustion chamber thus sets the temperature for the initial reaction of the mineral material, which depends on

Educt and target product can be very different.

In the first combustion chamber, the energy generated is primarily used to provide the required energy

To provide energy for the thermal treatment and thus for the chemical processes taking place in the mineral material. For example, the temperature can be maintained in this way. One advantage is that the amount of

Fuel supply and thus the amount of heat generated in the first combustion chamber can be directly linked to the amount of mineral material supplied

Temperature can therefore be adjusted independently via the fuel supply to the second combustion chamber. This decouples the process parameters (reaction temperature) and the sales volume and thus leads to a consistent product regardless of throughput. At the same time it is possible to enter the first one

Combustion chamber can be set to a very high temperature in order to enable a first treatment stage at a high temperature, which can be well above what the rest is used for

Entrained flow calciner or other system components are designed.

To achieve this, constriction is essential. Due to the smaller cross section in the constriction, the flow velocity is higher there than in the first

Combustion chamber (and also in the second combustion chamber). But since that is the case

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Material introduced during the material entry encounters a higher flow velocity when falling in the area of the constriction, the mineral material is prevented from sagging (getting into) the second combustion chamber. This prevents the temperature in the second combustion chamber from being influenced by the chemical processes during the thermal treatment of the mineral material.

By dividing the burner chamber into two combustion chambers, two different combustion chamber environments can be created, which is also an advantage compared to a single combined combustion chamber. This results in a local burnout of the fuel due to the significant excess of oxygen in the second combustion chamber, with the possible formation of a flame before it enters the first

Combustion chamber ensured. This enables secure monitoring of the

Burnout, even if the combustion air temperature entering from below is below the ignition temperature of the fuel. In the first one above

The combustion chamber then allows the gas temperature well above the ignition temperature of the fuel to operate close to the stoichiometric oxygen requirement. By significantly reducing the oxygen content and introducing the material into the first

Combustion chamber, there is also a preferably flameless oxidation of the

Fuel, which partly also extends over the calcining line, the part of the calciner that extends above the first combustion chamber, also known as the calciner riser, and thus creates a homogeneous temperature profile across the process space.

In a further embodiment of the invention, the horizontal is

Cross-sectional area of the constriction is less than 75%, preferably less than 50%, of the horizontal cross-sectional area of the first combustion chamber. The horizontal cross-sectional area of the constriction is preferably less than 50% to 20%, particularly preferably less than 50% to 35%, of the horizontal cross-sectional area of the first

combustion chamber.

In a further embodiment of the invention is within or directly below the

A second temperature meter is arranged in the constriction. This makes it possible to...

The temperature in the gas stream at the entry into the first combustion chamber can be set specifically and completely independently of the amount of mineral material fed in.

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In a further embodiment of the invention, the second temperature meter is connected to a control unit. The control unit is used to regulate the

Fuel supply to the second combustion device is formed. This enables automatic control, which in particular enables a constant temperature. It is also possible to run targeted temperature programs, for example to produce different products.

In a further embodiment of the invention, the constriction has guide elements for swirling the gas stream. The guide elements can be designed, for example, in the form of guide plates installed in a threaded manner. In particular, the guide elements achieve a rotation of the gas flow.

In a further embodiment of the invention, the gas inlet points into the second

Combustion chamber guide elements for swirling the gas flow. The guide elements can be designed, for example, in the form of guide plates installed in a threaded manner. In particular, the guide elements achieve a rotation of the gas flow.

In a further embodiment of the invention, the second combustion device is for

Combustion of solid fuels, especially substitute fuels, is formed. For this purpose, the second combustion device can also be on the side of the second

Combustion chamber be arranged.

In a further aspect, the invention relates to a method for operating an entrained flow calciner according to the invention. In the second combustion chamber there is one

Gas temperature of over 1100 ° C, preferably from 1200 ° C to 1450 ° C, particularly preferably from 1350 ° C to 1450 ° C. Comparatively high temperatures are therefore possible in this transition area and thus as the initial temperature for the treatment of the mineral material, which, for example, causes a surface

Can allow for melting and can lead to other product properties.

In a further embodiment of the invention, the gas stream leaves the

Entrained flow calciner with a maximum temperature of 1100 °C to 1200 °C.

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In a further embodiment of the invention, the first combustion device is in

Dependence on the amount of material supplied by the material feed is controlled.

By using the second combustion device to adjust the temperature and the first combustion device, operation is possible even with fluctuating quantities

Material application is very easy.

In a further embodiment of the invention, the first combustion device is controlled by means of a temperature measurement within or at the end of the calciner line. The amount of energy supplied is adjusted depending on the material supply in order to keep the required process temperature for the implementation constant. through the

Using the second combustion device to adjust the temperature at the gas inlet into the first combustion chamber and the process temperature-controlled first combustion device, operation is possible very easily even with fluctuating quantities of material applied.

Exemplary embodiments of the entrained flow calciner according to the invention are explained in more detail below with reference to drawings.

Fig. 1 first exemplary embodiment

Fig. 2 second exemplary embodiment

Fig. 3 entrained flow caleinator in an overall system

A first exemplary embodiment is shown schematically in FIG. Shown is the lower area of an entrained flow calciner with two combustion chambers 10, 20. Gas enters through the gas supply 50 from below. The gas can, for example, come from one

Rotary kiln or a material cooler. The gas stream is therefore preferably already at an elevated temperature. In the second combustion chamber 20 the

Gas flow brought to the desired temperature by means of the second combustion device 22. Here, the second combustion device 22 can be, for example, a natural gas burner. It can also be a combustion device for substitute fuels or an external hot gas generator. Above the second combustion chamber 20 and below the first combustion chamber 10, the constriction 30 is arranged connecting these two. In the example shown, the diameter of the constriction is only half as large as the diameter of the first combustion chamber 10. The cross-sectional area of the constriction 30 is therefore only 25% of the cross-sectional area of the first combustion chamber 10.

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This accelerates the gas flow in the constriction and prevents mineral material from sinking from the first combustion chamber 10 into the second combustion chamber 20. The first combustion chamber 10 has a first combustion device, for example a natural gas burner. The first combustion chamber 10 also has a

Material feed 14, via which the mineral material to be thermally treated is introduced. The mineral material is then mixed with the gas stream

Gas flow is transferred from the first combustion chamber into the calciner riser 40, at the end of which a separation cyclone is usually arranged.

The second embodiment shown in Fig. 2 differs from the first

Embodiment through active control of the fuel supply. In the calciner

Riser 40 directly above the first combustion chamber 10 is a first

Temperature meter 16 arranged, which is read via a control unit 60. Depending on a predetermined temperature, the control unit 60 regulates the fuel supply to the first combustion device 12 and can thus maintain a constant flow of material in the material supply 14 even if the material flow fluctuates

Ensure product quality. Accordingly, there is a second one in the constriction 30

Temperature meter 26 arranged. The second temperature meter 26 is via a

Control unit 60 read out, the control units 60 also being a single one

Control unit 60 can be, which is also preferred. In particular, the

Control unit 60 can be integrated into a plant control center. The control unit 60 regulates the fuel supply to the second combustion device 22 depending on a predetermined temperature. This achieves a constant temperature and also avoids initial overheating of the product.

Fig. 3 shows the entrained flow calciner 1 according to the invention in an exemplary system, the entrained flow calciner 1 itself being shown in a very simplified manner. in one

Preheater 70, which preferably consists of a cascade of two to six

Consists of direct current heat exchangers with downstream separation cyclones

Material is preheated and then fed to the material feed 14. In the

The hot gas is led countercurrently from the entrained flow calciner 1 into the preheater 70, where it releases most of its thermal energy to the material. The

After the calciner riser 40, the entrained flow calciner 1 has a separation cyclone 42, from which the material is preferably transferred to a material cooler 80. The

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Material cooler 80 is preferably a cascade of two to five

Direct current heat exchangers with downstream separation cyclones. In the

Material cooler 80, the finished product releases most of its thermal energy to the inflowing gas, which is then preheated and fed to the flux flow calciner 1.

Reference number 1 entrained flow calciner first combustion chamber 10 12 first combustion device 14 material supply 16 first temperature meter 20 second combustion chamber 22 second combustion device 26 second temperature meter 30 constriction 40 calciner riser 42 separation cyclone 50 gas supply 60 control unit 70 preheater 80 material cooler

Claims (13)

° BE2022/5067 patent claims 1. entrained flow calciner (1) with a first combustion chamber (10), the first combustion chamber (10) having a first combustion device (12), the entrained flow calciner (1) having a material feed (14) into the first combustion chamber (10), thereby characterized in that the entrained flow calciner (1) has a second combustion chamber (20), the second combustion chamber (20) being arranged below the first combustion chamber (10), the second combustion chamber (20) having a second combustion device (22), with between a constriction (30) is arranged in the first combustion chamber (10) and the second combustion chamber (20). 2. entrained flow calciner (1) according to claim 1, characterized in that the horizontal cross-sectional area of the constriction (30) is less than 50% of the horizontal cross-sectional area of the first combustion chamber (10). 3. Entrained flow calciner (1) according to one of the preceding claims, characterized in that a second temperature meter (26) is arranged within or directly below the constriction (30). 4. entrained flow calciner (1) according to claim 3, characterized in that the second temperature meter (26) is connected to a control unit (60), the control unit being designed to control (60) the fuel supply to the second combustion device (22). 5. Entrained flow calciner (1) according to one of the preceding claims, characterized in that a first temperature meter (16) is arranged above the first combustion chamber (10). 6. entrained flow calciner (1) according to claim 5, characterized in that the first temperature meter (16) is connected to a control unit (60), the control unit (60) being designed to regulate the fuel supply to the first combustion device (12). 7. entrained flow calciner (1) according to one of the preceding claims, characterized in that the constriction (30) has guide elements for swirling the gas flow. 8. entrained flow calciner (1) according to one of the preceding claims, characterized in that the second combustion chamber (20) has guide elements for swirling the gas flow. 9. entrained flow calciner (1) according to one of the preceding claims, characterized in that the second combustion device (22) is designed for the combustion of solid fuels, in particular substitute fuels. 10. A method for operating an entrained flow calciner (1) according to one of the preceding claims, wherein in the second combustion chamber (20) a gas temperature of over 1100 ° C, preferably from 1200 ° C to 1450 ° C, particularly preferably from 1350 ° C to 1450 °C, is generated. 11. The method according to claim 10, characterized in that the gas stream leaves the entrained flow calciner (1) at a temperature of at most 1100 ° C to 1200 ° C. 12. The method according to any one of claims 10 to 11, characterized in that the first burning device (12) is controlled depending on the amount of material supplied through the material feed (14). 13. The method according to any one of claims 10 to 12, characterized in that the first combustion device (12) is controlled as a function of the temperature detected by the second temperature meter (26).