DD205157A1 - METHOD AND DEVICE FOR THE HEAT TREATMENT OF FINE-COATED MATERIAL - Google Patents

Abstract

The invention relates to a method and apparatus for heat treatment of feinkoernigem material, preferably cement raw meal. The object and the object of the invention is to avoid further the effect of calcination and to avoid deflagration in the calcining break. This is achieved by adjusting the amounts of furnace exhaust gas so that at the end of d. Brennst.die Sauerstoffkomzent.im Tertiaerluft exhaust gas mixture of the reactor lock is less than 13% and after commissioning of the kr burner, the oxygen concentration is more than 13% and that for better Ausnutz.des Waermeinhaltes the kiln exhaust already preheated or teilkalziniertes material d.Umgehungsleitungzugefuehrt.

Description

Method and device for heat treatment of fine-grained material

Field of application of the invention

The invention relates to a method and the associated apparatus for the heat treatment of fine-grained material, preferably cement raw meal, in particular for calcination with direct supply of a partial secondary air quantity drawn from the cooler into the calcining zone and mixing with the exhaust gases from the high-temperature range.

Characteristic of the known technical solutions

It is known that for better preparation of the raw material on the clinker burning process in a rotary kiln with upstream heat exchanger, the calcination of the raw material is carried out in a separate calcination reactor. The calcination reactors are equipped with one or more fuel introduction devices. By supplying fuel or »thermal energy into the calcination reactor, it is possible to achieve a decarbonization of the abandoned raw material up to 90 % o thereafter, the further heat treatment of the precalcined material in a sintering reactor, such as a rotary kiln, while the exhaust gases of the rotary kiln and the calcination -

- »- 232Λ05 3

reactor can be used to preheat the raw material.

From DE-AS 25 10 312 it is known to carry out the decarbonation not in a separate calcining reactor, but in the gas channel between the rotary kiln and the downstream heat exchanger system. The required combustion air is supplied through the rotary kiln and via a separate gas line from the radiator of a connecting line and mixed there.

According to DE-OS 24 16 528, the calcination of the material takes place in a conical-cylindrical calcination reactor in which a mixture of the kiln exhaust gases with the exhaust air from the boiler is also effected.

A disadvantage of these devices is that a low oxygen concentration is present through the mixing of the kiln exhaust gases with the secondary air quantity during the combustion of the fuel in the separate calcination reactor.

From DE-OS 24 36 079 it is known to operate a flood with the exhaust gases of the rotary kiln and the other flood with the exhaust gases of the calcination reactor in a twin-flow preheater. In this case, only the partial secondary air quantity is supplied to the calcining reactor as combustion air, which improves the burnout behavior of the fuel in this zone.

Disadvantage of this device is a complicated Anfahrverhalten the calcination, as must be done with insufficient preheated Teilsekundairluft.

In order to increase the degree of calcination of the material in the calcining reactor, it is known from DE-OS 27 24 654 to perform the KaI zinierpmzeß in two stages. It is advantageously possible to use different types of fuels

The disadvantage here is that the burn-out process is separated or interrupted by poorly combustible fuels through intermediary separator, which the entire

232405 3

Calcination process delayed and requires a greater height of the plant »

DE-PS 23 44 583 a known from several chambers calcining reactor is known, the lowermost chamber is acted upon with cooler exhaust air near the upper end of the uppermost chamber opens tangentially the furnace exhaust gas line into the calcining ¬ · This tangential gas supply has the task, the precalcined material discharged from the calcination reactor.

When using low-grade fuels in the calcination reactor, the height of the reactor is relatively large, since the fuel needs a long burn-out.

From GB-PS 960 863 it is known to carry out the calcination of the material in a calcining reactor designed as a fluidized bed reactor. In this case, a part of the secondary air from the cooler is used as combustion air in the calcining reactor. The hot exhaust gases emerging from the sintering unit are removed with the exhaust gases from the Calcining reactor mixed prior to entry into the cyclone preheater · Disadvantage of this invention is that only small degrees of calcination of the material are achieved with the fluidized bed reactor as a calcination, since at higher degrees of calcination, the material tends to caking, which leads to disturbances in the reactor ·

According to DD-WP 79 961 and 81 433 is known to arrange the cyclone calcining reactor under a shaft preheater having a direct connection via the kiln inlet channel with the rotary kiln · The material is the reactor exhaust from above by means of a barrier or the like against the furnace abandoned and leaves him below also by an appropriate barrier, in the cylindrical part of the calcining reactor supply lines for highly heated secondary air and tangentially and staggered burners are provided for firing.

- 2324053

By arranging additional stages as a calcining reactor, the overall height of the preheater is increased. This results in additional construction costs as well as additional expenditure by the conveying devices for the material.

There are also already known double-flow preheater systems with calcination · It is followed by each Vorwärmerflut a calcining reactor to which only the material is supplied to a flood, or the preheated material of both floods is fed to a reactor »Moreover, it is known to avoid buildup by alkali condensates either venting part of the fugitive-enriched hot gases from the system by means of a bypass or cooling the gas stream with cold, powdered material, with the batch-forming volatile materials condensing on the cold material and then with the material from the system The disadvantage of this method is that the supply of cold material or the discharge of hot gases worsens the effectiveness of the heat exchange process.

Furthermore, it is known to arrange an adjustable throttle for controlling the amount of combustion gas in the transition between rotary kiln and a mixing chamber for the kiln exhaust gas and the exhaust air cooler ·

Object of the invention

The aim of the invention is to further increase the effectiveness of the calcination, to achieve a trouble-free ignition of Kalzinierreaktorbrenner and to avoid deposits on the components of the preheater as far as possible.

- 5 - 232 4 05 3

Explanation of the essence of the invention

The object of the invention is to increase the residence time of the materials in the calcining reactor and to adjust the amount of oxygen in the calcining reactor so that deflagrations of the fuel in the calcining reactor are avoided.

According to the invention, the object is achieved in that when igniting the KR fuel, which is preferably pulverized coal, the Ofenabgasraenge which is partly axially over part of the bypass line in the calcining reactor, adjusted so that the oxygen concentration in the tertiary air-exhaust gas mixture Reactor lock is less than 13%. To ensure perfect combustion, the kiln exhaust gas levels are adjusted after commissioning of the KR burner so that the oxygen concentration in the tertiary air-exhaust mixture of the reactor lock is more than 13 % .

In order to achieve improved utilization of the heat content of the exhaust gases conducted via the bypass line and a reduction of alkali condensations, including the associated undesirable formation of deposits in the bypass line, according to the invention a partial flow of the material leaving the reactor cyclone above the reactor cyclone is above the constriction in the bypass line guided. In this case, the partial exhaust gas stream gives off its heat to the colder material, at the same time the volatile alkalis condense on the colder flour particles. Part of exhaust gas stream and material then pass together in the upper part of the reactor.

According to the invention registered in the bypass part stream of material may also be deposited in a cyclone from which the material is fed directly into the high temperature region of the reactor _e To increase the Kalziniergrades a partial material flow from the reactor cyclone is guided into the bypass passage according to the invention further and reenters the Nachkalzinationsbereich of the reactor, where the material is close to

- 6 - 232405 3

completely deacidified »

An improvement of the degree of calcination by increasing the material residence time in the calcination reactor is achieved by tangential feeding the guided over the bypass line furnace exhaust gases in the upper part of the calcination. The kiln exhaust gases are supplied in the same direction as the tertiary air. Due to this tangential entry mode, the swirl flow in the reactor, which is still weak due to the tangentially occurring tertiary air, is intensified and stabilized in the reactor. This effect is further improved by a tangential discharge of the gas-good mixture from the calcining reactor.

embodiment

The invention is explained below with reference to several embodiments. In the accompanying drawings show:

Pig. 1 shows the device according to the invention for feeding material into the bypass line

Pig. 2 shows the device according to the invention according to Pig. and additional separation of the material from the gas in the bypass line

Pig. 3 shows a variant according to the invention of the supply of material into the bypass line

Pig. 4 shows the device according to the invention

tangential discharge of the exhaust gas material mixture from the calcination reactor

According to the invention described in the patent WP C 04 B / 222 9 ^ 3 division of the kiln exhaust gases, which are quantitatively adjustable by the actuator H, according to the invention in the ignition of the pulverized coal fuel of the calcining reactor

- 2 3 2 4 0 5

the gas flows are adjusted so that the oxygen concentration in the tertiary air-exhaust gas mixture of the reactor lock 15 is less than 13 % . After start-up of the calcining reactor burners, the amounts of kiln exhaust gas are adjusted so that the oxygen concentration in the tertiary air-exhaust gas mixture of the reactor lock 15 is more than 13 % to ensure complete combustion of the pulverized coal.

According to the figure 1, a part of the exhaust gases coming from the rotary kiln is passed through the bypass line 2 for calcination reactor 4 · For better utilization of the heat content of these gases and to avoid buildup on the wall of the bypass line 2 is a Teilma terialstrom from the cyclone 6 by means of material The constriction 3 is at least 2/3 of the cross-sectional area of the bypass line 2. The other part of the material flow from the cyclone 6 is introduced via the material line 11 into the calcination reactor 4. The guided in the bypass line 2 material is further heated by the hot furnace exhaust partial flow. The entrained in the furnace exhaust partial vapor vapor alkalis are reflected on the relatively cold material, are supplied tangentially with the material through the gas flow in the upper part of the calcination 4 and are then transferred to the after-reaction channel 5 of the reactor 4.

2 shows a further embodiment of the invention is shown, wherein the registered in the bypass line 2 material is separated before entering the calcination reactor 4 by means of cyclone 8 from the gas stream. The further heated by the furnace exhaust gas in the bypass line 21 material passes through the material line 16 in the high temperature region of the calcination reactor 4 and takes there once again heat. As a result, a maximum heat absorption of the material is achieved, which is expressed in a high degree of calcination.

- 232405 3

FIG. 3 shows a variant of the feed of material into the bypass line 2. A partial material flow from the cyclone 7 downstream of the calcining reactor 4 is fed via a material line 10 to the bypass line 2, the other part of the cyclone 7 The already partially calcined material from the cyclone 7 is entrained in the bypass line 2 through the furnace exhaust partial flow, absorbs heat and is further decarbonated The entrained with the furnace exhaust gas material is tangential in the upper part of the Calcined 4 calcination and completely deacidified in Nachkalzinationskanal 5 »

To further stabilize and increase the swirl flow in the calcining reactor 4, the kiln exhaust gases which are conducted via the bypass line 2 are introduced tangentially and in the same direction as the tertiary air in the upper part of the calcination reactor 4. This stabilization increases the material residence time in the reactor by up to two times. This effect is further improved by a tangential discharge 13 of the exhaust gas material mixture from the calcining reactor 4 into the cyclone 7.

The advantages of the invention are that by setting the oxygen concentration in the tertiary air-exhaust gas mixture at the reactor deflagration when igniting the KR fuel, especially when using coal dust, avoided · That by feeding material into the bypass line, the heat content of the through Oven exhaust gases can be used even more effectively for preheating or "for calcination and that the precipitation in the bypass is reduced by the precipitation of the alkalis on this material." Another advantage of the invention is that the tangential junction of the bypass

232405 3

line in the calcination reactor and by the tangential deduction of the exhaust gas material mixture from the calcination reactor the material residence time is doubled by amplification and stabilization of the swirl flow in the calcining reactor.

Claims (4)

232405 3 invention claim 1β Process for the heat treatment of fine-grained material, preferably cement raw meal, in particular for calcination with direct supply of a partial secondary air quantity drawn from the cooler into the calcining zone and mixing with the exhaust gases from the Hoch.temperaturbera.ch, whereby the waste gases are divided into two partial streams, characterized by that the kiln exhaust gas streams, which are passed through the bypass line or directly into the calcination, are adjusted by means of actuator so that when igniting the calcination fuel, especially in coal, the oxygen concentration in Tertiärluft exhaust gas mixture of the reactor lock is less than 13% and after start-up of the burner the oxygen concentration is more than 13 % . 2 «Device according to item 1, characterized in that a material line (11) of the cyclone (6) in the calcination reactor (4) and the other material line (12) above the constriction (3) opens into the bypass line (2) and that the Narrowing (3) is at least 2/3 of the cross-sectional area of the bypass line (2). 232405 3 · Device after. Item 1, characterized in that a material line (9) of the cyclone (7) in the rotary kiln (1) and the other material line (10) above the constriction (3) opens into the bypass line (2), 4. Device according to point 2 and 3 », characterized in that the bypass line (2) opens tangentially and in the same direction as the tertiary air supply in the upper part of the calcining reactor (4) and that the outlet (13) of the calcining reactor (4) is arranged tangentially , - For this 4 sheets drawings -