DE2451115A1 - PROCESS FOR GAS AND MATERIAL CONDUCTION THROUGH A DEVICE FOR HEAT TREATMENT OF POWDER-MADE MATERIALS, IN PARTICULAR OF CEMENT RAW MATERIAL, AND DEVICE FOR CARRYING OUT THIS PROCESS - Google Patents

Description

Patent attorneys Olp! .-! Ng. R. B ε E T Z eerv

DIp »-1n ₃ . K. LAMPRECHT

Dr. ~ lng. R-BEETZJr, 2451115

8Münohen22, Stolnedorfetr »It

233-23-345P October 28, 1974

Prerovske strojirny, närodni podnik, PREROV (CSSR)

Process for gas and material conveyance through a device for the heat treatment of powdery products Materials, in particular of cement raw material, and device for carrying out this process

The invention relates to a method for guiding gas and material through a device for heat treatment of powdery materials, in particular of cement raw material in the dry process in clinker production, wherein the raw material calcination and the subsequent sintering process are performed mutually separately, and an apparatus to carry out this procedure.

At present, modern heat treatment devices are being used For firing cement clinker in the dry process with up to 2.5 ~ for reasons of production and operational economy

233- (S 8439) -TE

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fan specific power of the rotary kiln in comparison with proposed a device of the same dimensions but with a conventional arrangement for the drying process, namely rotary kiln with upstream dispersion heat exchanger,

This significant increase in performance is made possible by the fact that the most heat-consuming process is during firing of cement clinker, i.e. the calcination, separately from the sintering process in a so-called dispersion calcination stage is carried out. As a result of this technological subdivision into two stages, it is necessary to also use the entire amount of To distribute heat energy (which was previously generated in a place) and any proportion of the heat in that place where the relevant stage of the technological process takes place.

The heat energy required for the calcination stage of the raw material is partly formed by the exhaust gases from the subsequent stage of the technological process, i.e. the sintering process, which mostly takes place in the rotary kiln, and partially the raw material burned directly in the room of this dispersion calcining stage. That means that it is in the combustion process with separate raw material calcination, two fuel combustion processes connected one after the other and taking place in separate rooms there, one process taking place in the rotary kiln, the other in the calcining stage. Every combustion process In addition to the fuel, the required amount of the most preheated combustion air must be supplied whose source is the clinker cooler lined up behind the rotary kiln, where the preheated combustion air passes through

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Cooling of the hot clinker is generated by means of supplied cold air. Part of the preheated to burn The air required for the fuel content in the rotary kiln is removed from the cooler through their mutual connection point fed. Part of the preheated air that you need to burn of the fuel content is required in the dispersion calcination stage, this stage is passed through a cooler this thus connecting pipe fed.

Those created in these two stages of combustion Combustion products must continue to be discharged as exhaust gases, their heat content in the upstream dispersion preheating stage is used to preheat raw materials.

It is, however, a necessary requirement that these two streams of exhaust gases be in a suitable location be combined into a single stream. This suitable point is in principle determined by the construction arrangement of the entire furnace series and thus by the type of calcining stage used and the dispersion preheater. That means, that at the point where the two streams are mixed, two separate branches exist, one of which is from Rotary kiln with subsequent waste pipe and the other of which includes the cooler with the dispersion calcining stage the subsequent parts of the device are formed up to the point of connection of the two flows connecting pipeline will.

Because the length of the lines and the design of the lined up parts in the individual line branches are different are, their flow resistances are also different

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-be nothing. However, this fact affects the basic distribution of the amount of exhaust gases flowing through these branches and having a single ventilator to vent all the flue gases is a satisfactory control of the technological process does not allow.

A well-known compensation of the air flow resistance in two line branches is the connection of one additive fan in the branch with greater resistance, which is here by the cooler and the dispersion calcination stage connecting tube of the preheated air is formed.

This solution, however, to a certain extent limits the heat value of this air, which can amount to ^{a maximum of 500 ° C. when passing through this fan.} Likewise, the operational reliability of the additive fan, unless it is preceded by a separator, is influenced by the considerable dust content of this air. The main disadvantage of this solution is that the maximum achievable in the cooler temperature of about 800 ⁰ C, the preheated air can not be exploited. In practice, however, this means an increase in the heat consumption of the furnace system.

Another known solution when using a source for the extraction of all exhaust gases is the activation a reduced part in the branch with the smaller resistance, which is usually the branch with the rotary kiln is where this reduced part creates constant drag. For regulatory reasons, however, it is necessary in the second branch a regulating element, e.g.

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Insert a flap or a slider, thereby reducing to a certain extent the amount of supplied to the individual heating points preheated combustion air can be regulated depending on the current operating status.

Although this solution requires the use of an additive fan, which was necessary in the previous solution, makes unnecessary, this solution, especially from the standpoint of operational reliability, cannot be considered optimal either will.

The aforementioned regulating element, i.e. the flap or the slide, does not have sufficient sensitivity to reaction and Accuracy that corresponds to modern process engineering.

Likewise, the reduced part, which for structural reasons is usually attached just behind the rotary kiln, i.e. at the point where considerably dusty exhaust gases ^{flow up to 1200 °} C., cannot be considered reliable.

It is an area where irregular approaches form that a variable calibration of the reduced Part and thus also cause a variable flow resistance. This fact makes a considerable one Effort through a constant removal of the approaches or instead through an automatic adjustment of both branches necessary.

The invention is based on the object of a method

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and a device for gas and material management of the type mentioned at the beginning with combustion air preheating in the sintered material cooler and utilization of the exhaust gas heat content to preheat the material so that you can with as possible simple means greater operational reliability and easier regulation with less energy consumption achieved.

The object of the invention, with which this object is achieved, is first of all a method for gas and material guidance by a device for the heat treatment of powdery materials, in particular of cement raw material during Dry process of clinker production, with raw material calcination and the subsequent sintering process in mutually separated heat stages, one calcining and one Sintering stage, in which the sintered material is mixed with preheated combustion air from the cooler Fuel is burned, and the heat content of the exhaust gases from these heat levels continues to preheat the raw material is used in a preheating stage, with the indicator that from the calcining and the sintering stage resulting flue gases are introduced separately into separate branches of the preheating stage, where through a direct Contact in countercurrent flow the raw material is preheated, that this is then from each branch of the preheating stage in a common calcining stage is introduced and that the exhaust gases from "the calcining and sintering stages only through the associated Branch of the preheating stage can be withdrawn by means of separate fans, which at the same time part of the preheated Combustion air from the cooler to mix with

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Suck in fuel in the calcining and sintering stages.

The invention also relates to a device to carry out this process, with the indicator that it consists of two mutually independent line branches for Gas guide is composed, wherein the first branch is formed by a pipeline which is in the The calcining stage opens, the outlet pipe of which is connected to the gas inlet part of one of the preheating branches, whose outlet pipe for the gases opens directly into the inlet of one exhaust fan, and the second branch is formed by the rotary kiln, the outlet pipe of which is connected to the gas inlet part of the other preheater branch is connected, the outlet pipe for the gases opens directly into the inlet of the other exhaust fan.

The invention is explained in more detail with reference to the exemplary embodiment illustrated in the single figure of the drawing explained.

The device consists of a dispersion preheating stage, which is formed by two preheating branches M and 5, a dispersion calcining stage 1, the rotary kiln 2 and the clinker cooler 3 with fan 22. Each of the two preheating branches ¹ J, 5 has its own fan 6 or 7. The cement raw material is fed separately to the two preheater branches H ^{and 5 through pipelines 13 and l 1} } via automatic metering devices 15, 16. The preheated raw material is fed from both preheating branches 4, 5 through pipes 17 and 18 to the common dispersion calcining stage 1, where the heat generated by the combustion of the fuel supplied by the burner 20 is used and the predominant

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de part of the calcination reaction comes about. This raw material is from the dispersion calcining stage 1 through the pipe fed to the rotary kiln 2, where by the incineration The heat generated by the fuel supplied by the burner 21 completes the calcination and the sintering process comes about.

The burnt-out clinker is fed to the cooler 3, where it is cooled by the supplied air.

The portion of the preheated air of high temperature from the cooler 3 is partly fed directly to the rotary kiln 2 and partly through the pipeline 10 to the dispersion calcining stage 1. The portion of the air from the cooler 3 of low temperature is discharged by the fan 22. The combustion gases from the rotary kiln 2 are introduced through the pipe 8 into the preheater branch % , where they give off part of the heat to the cement raw material, after which they are discharged through the outlet pipe 12 by means of the fan 6.

The combustion gases from the dispersion calcining stage 1 are fed through the pipe 9 to the second preheater branch 5 supplied, where they also give off part of their heat content to the cement raw material and finally through the outlet pipe 11 are discharged by means of the fan 7.

So each of the two burn points has a own gas management system, what their relative independence enables; the disturbance created in one combustion system does not directly affect the other Combustion system off.

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The activation of a fan in each of the two gas supply branches enables fine and economical regulation of the gas volume. This allows the insertion of an additive No fan in the branch of the preheated secondary air line for the dispersion calcining stage, whereby the disadvantages mentioned in relation to the known prior art can be eliminated.

The use of slides and throttle valves can also be dispensed with, and there is no need for reduced ones in the gas duct Place to be queued, thereby increasing the operational reliability of the oven series and the risk of Adhesion is reduced. It is also advantageous that the COp-containing combustion gases in the dispersion calcining stage need not be fed from the rotary kiln.

It is known that the greater the COp content in the Gases when the limestone is dissociated, the slower this reaction takes place. The management of the combustion gases This calcination reaction cannot take place from the rotary kiln outside the dispersion calcining stage influence negatively.

The use of the furnace series with a dispersion calcining stage is particularly advantageous for higher outputs for which the dispersion preheater also has other reasons expediently has two branches.

The present invention requires the installation of two parallel disperse preheat branches. Since the

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Dispersion preheaters are adaptable from the standpoint of performance, both branches of the preheater can preferably be constructed of the same dimensions and the possible differences in the heat content of the incoming gases can be corrected by different amounts of the raw material introduced.

This means that the raw material is preheated evenly in both branches of the preheater and one approximately reached the same temperature of the exhaust gases.

Since the combustion gases from the rotary kiln are not passed through the dispersion calcining stage ; the CO 2 content in the exhaust gases becomes smaller at this stage, which is advantageous from the point of view of the calcination process.

By introducing the invention, a greater operational reliability of the heat treatment stages is achieved, and their regulation is facilitated.

At the same time, the consumption of energy for burning clinker is reduced.

The process according to the invention can be used for any type of disperser preheater and for any calcining stage will.

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Claims (1)

- li - Claims 1. Process for gas and material conveyance through a device for the heat treatment of powdery materials, in particular of cement raw material in the dry process of clinker production, with raw material calcination and the The subsequent sintering process is carried out in mutually separated heat stages, a calcining and a sintering stage in which fuel mixed with preheated combustion air from the cooler of the sintered material is burned is, and wherein the heat content of the exhaust gases from these heat levels continues to preheat the raw material in a preheating stage is used, characterized in that the resulting flue gases from the calcining and sintering stages are separated into separate branches of the preheating stage be introduced where by direct contact in the downward flow the raw material is preheated so that it is then transferred from each branch of the preheating stage to a common calcining stage is introduced and that the exhaust gases from the calcining and sintering stages only through the associated Branch of the preheating stage can be withdrawn by means of separate fans, which at the same time part of the preheated Suck in combustion air from the cooler to mix with fuel in the calcining and sintering stages. 2. The method according to claim 1, characterized in that by independent regulation of the separate fans 50981 8/1113 the change in the amount of the proportions of combustion air sucked into the calcining stage and the sintering stage is effected depending on the determined content of oxygen in the exhaust gases behind these stages and that according to the amount and the temperature of the exhaust gases in front of these independent fans, the amount of the in the preheating stage to be given up raw material and the distribution in their individual branches is regulated. 3. Apparatus for performing the method according to claim 1 and 2, characterized in that it consists of is composed of two mutually independent line branches for conducting gas, the first line branch is formed by a pipe (10) which opens into the calcining stage (1), the outlet pipe (9) of which connected to the gas inlet part of a preheating branch (5) whose outlet pipe (11) for the gases opens directly into the inlet of an exhaust gas fan (7), and wherein the second line branch is formed by the rotary kiln (2), the outlet pipe (8) of which is connected to the Gas inlet part of the other preheater branch (4) connected is, the outlet pipe (12) for the gases opens directly into the inlet of the other exhaust fan (6) . k. Apparatus according to claim 3 » characterized in that the outlet pipes (17, 18) of the preheater branches (5, 4) open into a common calcining stage (1) to guide the preheated raw material. 50981 8/1113 5. Device according to claims 3 and 4, characterized in that that the preheating stage by at least two preheating branches (4, 5), which run parallel in the device are switched on for the heat treatment, is formed. 6. Device according to claims 3 to 5- »characterized in that that the calcining and preheating stage (1; 4, 5) are preferably dispersion stages. 7. Device according to claims 3 to 6, characterized in that the dispersion preheating branches (4, 5) of the raw material preferably have the same heat transfer surfaces
to have. 8. Device according to claims 3 to 7, characterized in that in each dispersion preheater branch (4, 5) of the raw material separately a feed pipe (13, 14)
of the raw material opens, which is provided with a mutually independent metering device (15 or 16). 50981 8/1113 ^{L e} erseif _e