EP0000739A1 - Process and apparatus for making cement in a fluidized bed - Google Patents

Abstract

The invention relates to a method and a device for producing cement by firing powdered raw material in a fluidized bed. Before it is introduced into the fluidized bed together with fuel (15), preheated air (27) and a recycled part of the fired material (11), the preheated raw material is pre-calcined to a high degree of deacidification with additional fuel in a precalcination zone (2) . The material passes from the fluidized bed into a cooling zone (5) located directly below, the cooling air flow of which is introduced into the fluidized bed partly from below (19) and partly from the side (30). The result is very stable operation of the fluidized bed, an evenly fired end product and low heat consumption.

Description

The invention relates to a method for producing cement by firing powdered raw material in a fluidized bed, into which preheated raw material, fuel, preheated air and a recycled part of the fired material are introduced, the material discharged from the fluidized bed subsequently being passed through a cooling zone by a Cooling air flow is cooled.

It is known to burn granulated cement raw material in a fluidized bed ("cement-lime gypsum", 1970, pp. 343 to 347 and DE-AS 1 433 913). The disadvantages here are the effort involved in granulating the raw material and the inadequate uniformity of the heat treatment of the inner and outer material zones of the granules.

To avoid these disadvantages, attempts have also been made to burn powdered cement raw material in a fluidized bed (DE-AS 1 156 012, DE-OS 1 696 690 and "Zement-Kalk-Gips", 1971, pp. 571 to 573). This is in the fluidized bed In addition to powdered raw material, fuel, combustion and loosening air, a recycled part of the fired material is also introduced as so-called "seed clinker" so that a continuous grain growth of the clinker particles is achieved in the fluidized bed by the addition of the raw meal. The raw material and the air are preheated into the fluidized bed before being fed. The fired clinker is withdrawn from the fluidized bed through an overflow or a central outlet and cooled in a separate cooler.

In the practical implementation of this method, considerable difficulties have arisen which have hitherto ruled out implementation on an industrial scale. So far, it has often proven difficult to distribute the preheated raw material and fuel quickly and evenly in the fluidized bed and to stabilize the operation of the fluidized bed properly. Due to the existing grain belt, there is a certain separating effect in the fluidized bed and thus a decreasing gap level (the gap level (ratio of empty volume to total volume of a fluid bed).

The problem with the known process is still the strong alkali vaporization when burning in the fluidized bed. This results in highly alkalihalti ^g s raw materials an extremely high alkali content in the Exhaust gases from the fluidized bed, which in many cases excludes the use of these exhaust gases for preheating the raw material - and thus leads to an undesirably large heat requirement.

The invention is therefore based on the object of avoiding these deficiencies to provide a method for firing powdered cement raw material in a fluidized bed, which is characterized by a particularly stable operation of the fluidized bed, a very evenly fired end product and a comparatively low heat consumption and also the production of Cement clinker with particularly low alkali content permitted.

• a) Das vorgewärmte Rohmaterial wird vor Aufgabe in die Wirbelschicht in einer Vorkalzinationszone mit zusätzlichem Brennstoff bis auf einen Entsäuerungsgrad von mindestens 40%, vorzugsweise von 80 bis 95%, vorkalziniert;
• b) aus dem unteren Bereich der Wirbelschicht gelangt das gebrannte Gut in eine unmittelbar darunter befindliche, die Kühlzone bildende Gutschüttung;
• c) ein Teil des Kühlluftstromes wird von unten her und ein weiterer Teil von der Seite her in die Wirbelschicht eingeführt.

This object is achieved according to the invention by combining the following features:

• a) The preheated raw material is pre-calcined in a precalcination zone with additional fuel to a degree of deacidification of at least 40%, preferably from 80 to 95%, before being fed into the fluidized bed;
• b) from the lower region of the fluidized bed, the fired material passes into a bed of material located immediately below and forming the cooling zone;
• c) Part of the cooling air flow is introduced from below and another part from the side into the fluidized bed.

According to the invention, there is extensive deacidification (precalcination, ie expulsion of the C0 ₂ ) of the raw material before it is fed into the fluidized bed. As a result, the fluidized bed is relieved of a large part of the heat work that would otherwise have to be done, which has significant advantages: the fluidized bed can be dimensioned smaller, requires less fuel and delivers a smaller amount of exhaust gas. The substantial reduction in the amount of exhaust gas from the fluidized bed makes it possible, in the case of a particularly high alkali content of the raw material, to dispense with the use of these exhaust gases for preheating and precalcination of the raw material, in whole or in part, without significantly increasing the heat requirement.

By introducing part of the cooling air flow from below and a further part from the side into the fluidized bed, rapid and even distribution of precalcined material and fuel in the fluidized bed, particularly uniform heat treatment of the material and very stable operation are achieved the fluidized bed.

The significantly improved combustion conditions in the fluidized bed due to the strong precalcination and the rapid, even distribution of precalcined material and fuel in the fluidized bed also ensure good functioning of the cooling zone arranged directly under the fluidized bed and in particular closes Be drive disruptions due to caking of goods in the cooling zone. The method according to the invention thus delivers very homogeneously fired clinker beads of approximately uniform grain size.

The rapid and uniform distribution of the pre-calcined material in the fluidized bed can be further promoted by the fact that the pre-calcined material is introduced into the fluidized bed from the side by part of the cooling air flow, preferably with a very high pulse between 5 and 10 kps.

In the lower region of the fluidized bed intended for the introduction of the pre-calcined material, a cross-sectional constriction advantageously sets approximately the same gap level as in the upper region of the fluidized bed, expediently a gap degree between 0.5 and 0.8, preferably between 0.6 and 0.7. With this measure, a particularly good distribution of the pre-calcined material in the fluidized bed is achieved even if the material insertion point is very deep, i.e. just above the cooling zone.

At least part of the fuel is expediently introduced into the fluidized bed from below from below the surface of the fluidized bed, preferably approximately at the level at which the precalcined material is fed. Another part of the fuel can be on the surface of the fluidized bed or together with the recycled part of the fired material are introduced into the fluidized bed.

The part of the fuel which is pneumatically introduced into the fluidized bed from the side is preferably introduced into the fluidized bed together with the pre-calcined material, and advantageously at several locations distributed uniformly over the circumference of the fluidized bed. This results in a particularly rapid and even distribution of material and fuel in the fluidized bed.

For stable operation of the fluidized bed, it is also important that the quantity of material present in the fluidized bed is kept approximately constant regardless of fluctuations in the quantity of material supplied and removed. However, since a substantial increase in grain size occurs in the fluidized bed, the necessary constant maintenance of the quantity of material cannot be achieved by simple volumetric control of the quantity of material supplied and removed. According to an expedient embodiment of the method according to the invention, the quantity of material located in the fluidized bed is regulated as a function of a gas pressure measured in the fluidized bed. In the experiments on which the invention is based, it surprisingly turned out that a gas pressure measured in the fluidized bed is a very sensitive and reliable measure of the amount of material present in the fluidized bed, so that the latter can be kept constant as a function of the gas pressure (by either the quantity of material discharged from the fluidized bed or the cooling zone or the quantity introduced into the fluidized bed. Quantity or both quantities can be controlled accordingly). The quantity of material located in the fluidized bed is expediently regulated as a function of the difference between a gas pressure measured in the fluidized bed and a gas pressure measured in the exhaust gas line of the fluidized bed, since an increase in the amount of exhaust gas in the fluidized bed has no influence on the setpoint value in such a differential pressure control .

For optimal operation of the fluidized bed, it has proven to be advantageous if about 50 to 90%, preferably about 2/3 of the total air supplied to the fluidized bed from below and 10 to 50%, preferably about 1/3, of the air from be introduced into the fluidized bed from the side.

The preheating and precalcination zone is expediently supplied with an adjustable part of the exhaust gases from the fluidized bed and preferably an adjustable part of the cooling air flow, while the remaining part of the exhaust gases from the fluidized bed is removed bypassing the preheating and precalcination zone. In the case of raw material with a particularly high alkali content, the entire exhaust gases of the fluidized bed can also be removed bypassing the preheating and precalcination zone and the latter can be fed exclusively with cooling air.

An embodiment of a system for performing the method according to the invention is illustrated in the drawing.

The plant contains a preheater 1, a precalcination zone 2 and a shaft-shaped reaction chamber 3 with a fluidized bed 4 and a cooling zone 5.

In the preheater 1, which can be designed, for example, as a multi-stage cyclone heat exchanger, the pulverulent raw material fed in at 6 is preheated in countercurrent by hot gases (arrow 7) and then passes (arrow 8) into the precalcination zone 2, where it is caused by the hot exhaust gases (arrow 9) of the reaction chamber 3 and additional fuel (arrow 10) is very high, preferably to a degree of deacidification of 80 to 95%.

The pre-calcined material is then fed (arrows 11, 12) to conveying lines 13, 14, via which it is pneumatically introduced into the fluidized bed 4 along with fuel 15 or 16 at least two mutually opposite points (arrows 17).

The clear cross section of the reaction space 3 is narrowed in the region of the mouth of the delivery lines 13, 14 and widens conically upwards from this feed zone. The cross section of the reaction chamber 3 and the flow velocities of the air are dimensioned so that in the lower region of the fluidized bed intended for the introduction of the precalculated material, ie approximately at the level of the conveying lines 13, 14, approximately the same gap level, preferably between 0.6 and 0.7, as set in the upper region of the fluidized bed.

In the fluidized bed 4, the pre-calcined material is fired into cement clinker. After a certain clinker size has been reached, the fired material reaches the cooling zone 5, to which a cooling air flow (arrows 19) is fed from below through the air-permeable base 18.

The cooled goods are drawn off by a rotating discharge device 20 (arrow 21). Part of the material is recycled into the fluidized bed 4 as seed clinker (arrow 22).

A part of the cooling air flow identified by the arrows 23 is introduced into the fluidized bed 4 as loosening and combustion air from below. Another part (arrow 24) is drawn off laterally on the circumference of the upper region of the cooling zone 5 by an air extraction line, possibly dedusted in a cyclone 25 and by a fan 26 to the delivery lines 13, 14 as conveying air for the pre-calcined material (arrows 11, 12) and the fuel (arrows 15, 16) supplied (arrows 27, 28).

Another part of this air conveyed by the blower 26 can - expediently below the level of the conveying lines 13, 14 - as additional sides air are introduced into the fluidized bed 4 (arrows 29, 30).

Another portion of the air conveyed by the blower 26 to the cooling zone 5 can be fed to the precalcination zone 2 as additional combustion air (arrow 31). Any excess air (arrow 32) can be discarded or otherwise used. Likewise, a certain proportion of the exhaust gases from the fluidized bed 4 can be diverted, bypassing the precalcination zone 2 and the preheater 1, in particular if the alkali content is high (arrow 33).

To regulate the amount of material in the fluidized bed 4, the system contains four pressure measuring points 34, 35, 36 and 37, of which the pressure measuring point 34 lies approximately in the area of the material introduction, the measuring point 35 approximately to 1/3 to 1/2 the height of the fluidized bed 4, the pressure measuring point 36 in the upper third of the fluidized bed and the pressure measuring point 37 in the exhaust pipe of the fluidized bed.

The four pressure measuring points are connected to a pressure transducer 38 which is connected to a regulator 39. This regulator 39 acts on the one hand on the discharge device 20 (control line 40) and on the other hand on a feed metering device 41 (control line 42).

The controller 39 keeps the quantity of material in the fluidized bed 4 constant, for example by being discharged by the controller 39 direction 20 in each case only the quantity of good located above the target value is discharged from the cooling zone 5 and thus from the fluidized bed 4 or by supplying a quantity of good missing from the target value in each case through the good feed metering device 41. A pressure value supplied by the pressure measuring points 34 to 37 is used as a measure of the quantity of material in the fluidized bed 4, for example the difference between the pressures determined at the measuring points 34 and 37.

• In der Wirbelschicht (einschließlich ihrer engsten Stelle im Bereich der Gut- und Brennstoffeinführung) wird eine Gasgeschwindigkeit von ca.
• 6 m/s und ein Lückengrad (Verhältnis von Leervolumen zu Gesamtvolumen der Wirbelschicht) von etwa 0,65 eingestellt; in der Kühlzone beträgt die Gasgeschwindigkeit ca. 2 m/s und der Lückengrad etwa 0,4 oder weniger.

The following example serves to further explain the invention:

• In the fluidized bed (including its narrowest point in the area of material and fuel introduction) a gas velocity of approx.
• 6 m / s and a gap degree (ratio of empty volume to total volume of the fluidized bed) of about 0.65; in the cooling zone the gas velocity is approx. 2 m / s and the gap degree is approx. 0.4 or less.

The grain size of the seed clinker is 2 to 4 mm; the ratio of raw flour / seed clinker is 4: 1.

The preheated and pre-calcined material is introduced into the fluidized bed 4 at a temperature of approximately 840 ° C. The temperature in this fluidized bed is between 1300 and 1350 ° C. In the cooling zone 5, the material is cooled to a temperature of 80 to 120 ° C.

The loss on ignition of the raw material after the preheater is 5%. The grain size of the deacidified raw material is 44%> 90µ and 8.8%> 200µ.

The air volumes can be selected as follows: 1.00 Nm ³ / kg of clinker are fed to the cooling zone 5 from below. Of this, 0.33 Nm ³ / kg Kl get directly into the fluidized bed from below (arrows 23), while 0.67 Nm ³ / kg Kl are drawn off laterally (arrow 24) from the cooling zone. From this latter part, 0.17 Nm ³ / kg Kl as conveying air (arrows 27, 28) for precalcined material and fuel enter the fluidized bed 4 from the side, while 0.5 Nm ³ / kg Kl directly (arrow 31) Precalcination zone 2 are supplied. An equal amount of air (0.5 Nm '/ kg Kl) reaches the precalcination zone 2 as exhaust gases from the fluidized bed (arrow 9).

The differential pressure measured between the pressure measuring points 34 and 37 is between 800 and 1200 mm WS, the differential pressure between the pressure measuring points 35 and 37 between 250 and 400 mm WS.

Claims (10)

1. A process for producing cement by firing powdered raw material in a fluidized bed, into which preheated raw material, fuel, preheated air and a recycled part of the fired material are introduced, the material discharged from the fluidized bed subsequently being cooled in a cooling zone by a cooling air stream is characterized by the combination of the following features: a) The preheated raw material is pre-calcined in a precalcination zone with additional fuel to a degree of deacidification of at least 40%, preferably from 80 to 95%, before being fed into the fluidized bed; b) from the lower region of the fluidized bed, the fired material passes into a bed of material located immediately below and forming the cooling zone; c) Part of the cooling air flow is introduced from below and another part from the side into the fluidized bed. 2. The method according to claim 1, characterized in that the pre-calcined material is introduced from the side into the fluidized bed by part of the cooling air flow, preferably with a pulse between 5 and 10 kps. 3. The method according to claim 2, characterized in that in the lower region of the fluidized bed determined for the introduction of the pre-calcined material, a cross-sectional constriction sets approximately the same gap degree as in the upper region of the fluidised bed, preferably a gap degree between 0.5 and 0.8 . 4. The method according to claim 1, characterized in that at least part of the fuel below the surface of the fluidized bed, preferably approximately at the level of the supply of the pre-calcined material, is introduced from the side into the fluidized bed. 5. The method according to claims 2 and 4, characterized in that at least part of the fuel together with the pre-calcined material at several, preferably evenly distributed over the circumference of the fluidized bed, introduced from the side by a part of the cooling air flow into the fluidized bed becomes. 6. The method according to claim 1, characterized in that the quantity of material located in the fluidized bed as a function of a gas pressure measured in the fluidized bed, preferably as a function of the difference between a gas pressure measured in the fluidized bed and a gas pressure measured in the exhaust gas line of the fluidized bed, is regulated. 7. The method according to claim 1, characterized in that about 50 to 90%, preferably about 2/3 of the total air supplied to the fluidized bed from below and 10 to 50%, preferably about 1/3, of the air from the side be introduced into the fluidized bed. 8. The method according to claim 1, characterized in that the preheating and precalcination zone an adjustable part of the exhaust gases of the fluidized bed and preferably an adjustable part of the cooling air flow is supplied, while the remaining part of the exhaust gases of the fluidized bed is removed bypassing the preheating and precalcination zone becomes. 9. Device for performing the method according to claims 1 and 2, characterized in that a shaft-shaped reaction space (3) is provided which has a cooling zone (5) in the lower region and above it a fluidized bed (4), further preferably as a multi-stage Counterflow heat exchanger trained preheater (1), which contains a pre-calcination zone (2) supplied with additional fuel (10), and that at least one air extraction line (arrow 24) is connected to the periphery of the upper region of the cooling zone (arrow 24) and is connected via a blower (26) with a pneumatic conveying line (13, 14) introducing the pre-calcined material into the fluidized bed (4), and a line introducing a further air flow into the fluidized bed (4) from the side (arrows 29, 30) and is preferably connected to a line (arrow 31) supplying combustion air to the precalcination zone (2). 10. The device according to claim 9, characterized in that the clear cross section of the reaction chamber (3) from the Guteinführzone (conveyor lines 13, 14) widens upwards.

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