DE3342686A1 - Installation for heat treatment of fine granular material - Google Patents

Abstract

The invention relates to an installation for the heat treatment of fine granular material, in which the material discharge line of the lowermost stage of the cyclone preheater also debouches into the tertiary airline, and between the debouchments of the material discharge lines of the lowest and second lowest stage of the cyclone preheater a cyclone separator is arranged whose material discharge line debouches into the feed chamber of the rotary kiln. An installation of this type achieves both effective combustion even of very slow-acting, lumpy solid fuels in the precalcination zone and a high degree of deacidification.

Description

Plant for the heat treatment of fine-grained goods

The invention relates to a system for the heat treatment of fine-grained Good according to the preamble of claim 1.

A system of the type required in the preamble of claim 1 is known for example from DE-A-27 52 323. The pre-calcination zone becomes in this case essentially through the one connecting the rotary kiln to the cyclone preheater Furnace exhaust pipe formed. In the tertiary air duct leading from the cooler to the precalcination zone The material discharge line of the second lowest stage of the cyclone preheater opens as well as a fuel supply. The product discharge line of the lowest level of the The cyclone preheater opens into the inlet housing of the rotary kiln or into the lowest Part of the furnace exhaust line.

In these known systems, the incineration of solid fuels in the pre-calcination zone in two respects difficulties: If the combustion air and fuel are poorly mixed, local Oxygen deficiency CO, which is relatively slow and only at sufficiently high levels Temperatures and oxygen content is implemented. This results in heat losses and Dangers for the downstream electrostatic precipitator.

Furthermore, the burning rate of the fuel particles is from the temperature and the oxygen content dependent. Due to the relatively low oxygen content The residence time of coarse fuel particles is sufficient in the pre-calcination zone in the pre-calcination zone (i.e. in the known systems in the furnace exhaust gas line between the confluence of the tertiary air duct and the lowest stage of the cyclone preheater) for a complete burnout.

The unburned coarse fuel particles are calcined with the Well separated in the lowest stage of the cyclone preheater and get into the Inlet of the rotary kiln, where it is due to significantly higher temperatures and residence times slowly continue to burn out.

This afterburning in the furnace inlet leads to high temperatures and to the formation of CO in the furnace inlet area, which can lead to dangerous deposits.

The invention is therefore based on the object while avoiding this Defects a system of the type required in the preamble of claim 1 so to train that also inert and / or relatively coarse solid fuel under Burn out completely to avoid the formation of CO.

At the same time, there should be a high in the pre-calcination zone Deacidification of the good can be achieved.

According to the invention, this object is achieved by the characterizing features of claim 1 solved.

Appropriate refinements of the invention are the subject of the subclaims.

In the system according to the invention, not only the material discharge line opens the second lowest stage of the cyclone preheater, but also the material discharge line the lowest stage of the cyclone preheater in the tertiary air line, with between A cyclone separator is provided at these two junctions, the material discharge line of which in the inlet housing of the rotary kiln (or in the lowest part of the Furnace exhaust pipe) is introduced. In this way it is achieved that the fuel In particular, inert and / or coarse fuel particles in the between the cyclone separator and the furnace exhaust line arranged section of the tertiary air line be introduced a second time into the tertiary air duct (namely into the section of the tertiary air duct leading to the cyclone separator) if they as they migrate through the furnace exhaust pipe to the lowest cyclone stage of the preheater are not yet completely burned out and for this reason in this lowest Cyclone stage are separated.

While the fine fractions of the fuel when they move for the first time burn out completely through the pre-calcination zone, thus becoming unburned Coarse fuel particles with the calcined material in the lowest stage of the cyclone preheater deposited and get back into the tertiary air line, where they are due to the high oxygen content burn out quickly and completely. The released Heat is used for a further deacidification of the flour-like product1 through this afterburning is highly deacidified before it gets into the rotary kiln.

The inventive solution is thus avoiding a CO formation a complete burnout is also very coarse and less reactive Fuels achieved, whereby even inert fuels are no longer extremely fine need to be ground up after even inert fuel particles in the react well with a very high excess of oxygen occurring afterburning.

Significant advantages result from the solution according to the invention also for the deacidification of the goods in the pre-calcination zone, as this is done twice Entrance of the entire property into the tertiary air duct and the post-combustion that takes place here a high degree of deacidification is guaranteed.

An embodiment of an inventive system is illustrated in the drawing.

The plant for the heat treatment of fine-grained goods, in particular for burning cement, contains a (only partially illustrated) multi-stage Cyclone preheater 1, of which only the lowest cyclone stage 2 and the second from the bottom Cyclone stage 3 is illustrated.

Furthermore, the system contains a rotary kiln 4, the exhaust gases through a furnace exhaust gas line 5 can be fed to the cyclone preheater 1.

Of a rotary kiln 4 downstream, not illustrated A tertiary air line 6 leads the cooler to the furnace exhaust gas line 5.

A cyclone separator 7 is arranged in this tertiary air line 6.

That lying between the cyclone separator 7 and the furnace exhaust gas line 5 Part 6a of the tertiary air line 6 is designed as a combustion chamber and with a Swirl burner 8 provided. Furthermore opens into the furnace exhaust gas line 5, downwardly inclined part of this section 6a of the tertiary air line 6, the material discharge line 9 of the second lowest cyclone stage 3 of the preheater 1.

In the section 6b of the tertiary air line leading to the cyclone separator 7 6 opens the material discharge line 10 of the lowest cyclone stage 2 of the cyclone preheater 1 a The lower region of this section 6b of the tertiary air line 6 is as Separating funnel 11 is formed, the material discharge line 12 of which into the inlet housing 13 of the rotary kiln 4 opens. In this inlet housing 13 continues to open Gutaustragsleitung 14 of the cyclone 7 a.

The function of the system is thus as follows: The flour-shaped to be preheated Well walks through the individual stages of the multi-stage cyclone preheater in a known manner 1- and is here by the hot exhaust gases from the rotary kiln 4 and the precalcination zone preheated. The preheated material separated in the second lowest cyclone stage 3 passes through the material discharge line 9 into the section 6a of the tertiary air line 6th

In the section 6a of the tertiary air line designed to form the combustion chamber 6 is solid fuel with a small amount of primary air through the swirl burner 8 introduced in the axial flow direction. This makes a very good meddling of the fuel in the combustion air (tertiary air coming from the cooler), and CO formation is avoided. The good to be calcined is only after the Added fuel mixture (confluence of the crop discharge line 9).

By suitable choice of the position and the swirl of the swirl burner 8 the temperature of the fuel-tertiary air mixture can be set before the product is added depending on the Reactivity of the fuel.

Fuel, farinaceous material and combustion air then flow through the section 6a of the tertiary air line 6 in the furnace exhaust gas line 5 and meet here on the hot furnace exhaust gases flowing in from below. Because of the high turbulence the sharp deflection into the adjoining section 5a of the furnace exhaust gas line 5 the result is an intensive mixing of material, fuel and combustion air. In this way, the fine fractions of the fuel are up to the point of entry into the bottom Cyclone stage 2 of the cyclone preheater 1 completely burned out.

Unburned coarse fuel particles are calcined with the Well separated in the cyclone stage 2 and arrive via the material discharge line 10 in the section 6b of the tertiary air line 6. Due to the high oxygen content (approx. 21%) now also coarser, previously unburned fuel particles burn very much quickly and completely. The heat released in the process causes a further deacidification of the good.

The material is then separated in the cyclone separator 7 and arrives Via the product discharge line 14 into the rotary kiln 4. The same applies to the product content, which already fail in section 6b of the tertiary air line and via the separating funnel 11 and the material discharge line 12 enter the inlet housing 13 of the rotary kiln 4.

The oxygen content of the tertiary air in the area of the section 6 formed combustion chamber is reduced by the upstream afterburning (in section 6b) only slightly. With 1% residual carbon in the partially calcined flour after cyclone stage 2, the oxygen content in the section is reduced by approx. 21% 6b of the tertiary air line 6 to about 16% in the section 6a of the tertiary air line.

The fuel quantities and temperatures in the pre-calcination zone (formed through the sections 6a and 6b of the tertiary air line 6 and through the furnace exhaust line 5 including its section 5a) are set so that the good which leaves the lowest cyclone stage 2, a degree of deacidification of approx. 70% is achieved has, which means a low calcining temperature and thus low heat consumption. During the afterburning in the tertiary air line 6, the degree of deacidification increases approx.

95% increased. Because of the very prevailing in the tertiary air duct With a low CO2 partial pressure, the deacidification runs more completely and simultaneously at lower temperatures.

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Claims (7)

Claims: 1. Plant for the heat treatment of fine-grained goods, a) containing a multi-stage cyclone preheater (1) for preheating the goods the exhaust gases of a downstream rotary kiln (4) b) a rotary kiln (4) for Burning the preheated goods; c) a cooler for cooling the fired material d) as well as one arranged between the rotary kiln (4) and the cyclone preheater (1), with additional fuel and via a tertiary air line (6) with exhaust air from the Cooler-supplied pre-calcination zone for further heating of the preheated goods before entering the rotary kiln (4), e) in which from the cooler to the kiln exhaust pipe (5) leading tertiary air line (6) the material discharge line (9) of the second lowest Stage (3) of the cyclone preheater (1) and a fuel feed (8) opens, characterized by the following features: f) also the material discharge line (10) of the lowest Stage (2) of the cyclone preheater (1) opens into the tertiary air line (6) a; g) between the confluence of the material discharge line (10) of the lowest stage (2) of the cyclone preheater (1) and the confluence of the Gutaustraggleitung (9) of the second bottom Stage (3) of the cyclone preheater (1) is a cyclone separator (7), whose Material discharge line (14) opens into the inlet housing (13) of the rotary kiln (4). 2. Plant according to claim 1, characterized in that the fuel supply (8) for the precalcination zone in the one between the cyclone separator (7) and the Oven exhaust gas line (5) arranged section (6a) of the tertiary air line (6) is. 3. Plant according to claim 2, characterized in that the between the cyclone separator (7) and the furnace exhaust line (5) arranged section (6a) the Tertiär.luftleitung (6) is designed as a combustion chamber. 4. Plant according to claim 2, characterized in that the fuel supply (8) is formed by a swirl burner, through the solid fuel with less Primary air is introduced into the tertiary air line (6) in the axial flow direction will. 5. Plant according to claim 2, characterized in that the material discharge line (9) the second lowest stage (3) of the cyclone preheater (1) between the fuel feed (8) and the furnace exhaust gas line (5) opens into the tertiary air line (6). 6. Plant according to claim 42, characterized in that the location and the swirl of the swirl burner (8) can be adjusted. 7. Plant according to claim 1, characterized in that the cyclone separator (7) leading section (6b) of the tertiary air line (6) into which the material discharge line 10 of the lowest stage (2) of the cyclone preheater (1) opens in the lower area is designed as a separating funnel (11) whose material discharge line (12) into the The inlet housing (13) of the rotary kiln (4) opens.