DE1200191B - Process and shaft ovens for dewatering, de-acidifying and roasting bulk goods with gas, mist or dust-like fuel in counterflow - Google Patents

Description

Process and shaft furnaces for dewatering, deacidifying and roasting Bulky materials with gaseous, mist or dusty fuel in countercurrent The invention refers to a shaft furnace for dewatering and deacidifying and roasting bulk materials with gaseous, mist or dusty fuel, with countercurrent flow between the material to be burned and air or gas is present.

The shaft furnace is characterized by the fact that of the listed Fuels, especially those with a high calorific value, such as heating oil, natural gas and coal dust, can be inserted directly into the furnace and without overheating of the items to be fired and Oven feed is a uniform firing product with a desired activity - e.g. B. Soft burned lime - is produced, whereby the cross-sectional output is over 12 tpd per square meter of furnace cross-section.

When deacidifying, dewatering or roasting you aim for a high burning zone with a temperature that is above the reaction temperature of fuel and The items to be fired and below the critical temperature of the items to be fired and the furnace lining, On the one hand, to achieve high performance in relation to the furnace cross-section and on the other hand, a reduction in the quality of the material to be fired and the formation of melt of the feed. To generate z. B. a uniform soft fired Lime, the temperature range is approximately between 820 and, depending on the level of contamination 1150 ° C. The higher the firing zone, the greater the cross-section generation be without degradation.

Under these conditions, the furnace output can vary according to the height of the firing zone in a first approximation proportional and, if in the upper combustion zone area, more fuel heat will be implemented as in the lower, disproportionate, because the individual pieces of firing at the beginning of the course of the reaction, e.g. B. deacidification of limestones without overheating can absorb more heat than before it ended. So it is known that limestone with a thin layer of lime, as it is in the upper combustion zone, better than can absorb heat or cool the flue gas with a thick layer of lime, without being thermally overloaded and without being in the activity at its later stage Use to decrease.

A low fuel heat consumption is only possible with a high combustion technology Efficiency possible, d. i.e., the fuel must have a slight excess of air burn from about 1.05 to 1.15 completely. In other technical stills As is well known, the safest way to achieve this is by intensive mixing of fuel and air in burners immediately before combustion and also through preheating the air, possibly also the fuel.

In a shaft furnace in which the material to be fired is in countercurrent the flue gas is, this type of combustion is for the above Purpose not feasible even with fuel with a low calorific value, such as blast furnace gas. All of the sensible heat from the combustion would then have to be outside the reaction zone of the furnace - called the deacidification zone when burning limestone - become free. Through this would z. B. with lime in the lower part of the deacidification zone, where it is almost finished Deacidification can hardly consume any heat, can be overheated too easily.

Therefore, the most economical fuel economy has become after this Cannot enforce proceedings. Rather, it is well known that the incineration is relocated from Z. B. blast furnace or generator gas directly into the furnace so that it lasts for a long time Mix away slowly with the combustion air and burn with a mild flame can. The heat released cannot then be massaged, but in a larger one Space to be distributed over the firing material and give off the heat. That part of the furnace is known as the burn zone.

The combustion is not uniform, however. Immediately in front of and above At the gas inlet, the gas forces the combustion air rising in the furnace in the space between two gas inlets and towards the middle of the furnace, if only introduced peripherally will. Merely with the air that diffuses into the area penetrates the gas inlets, some of it can burn - albeit with a lack of air. The greater the distance from each gas inlet, the greater the proportion of air to. At a certain distance there is the theoretical amount of air or a small excess air of 1.05 to 1.1 available. This is where the highest arises Temperature. Usually the gas inlets are so far apart that that this high temperature also forms on the feed between two gas inlets can, whereby it is most at risk at this point with good insulation. In addition, the material to be fired is at the point where the theoretical air requirement or a there is a slight excess of air, more heated than at the other places. Through this the result is an uneven degree of fire. Known measures, such as gas circulation or approval incomplete combustion, increase fuel consumption. Also the familiar Process, rather than through one level of fuel introduction, through two or three levels Bringing the gas into the furnace without any other measures has the same disadvantage, because the gas cannot mix sufficiently with atmospheric oxygen on the furnace wall.

For fuels with a higher calorific value, such as long-distance gas, heating oil, natural gas, take away the difficulties of creating a mild flame in the entire burning zone, especially if preheated air is used. Used on oil and coal dust one therefore combustion chambers for pre-combustion in order to have a better distribution option to have in the oven and to avoid combustion residues in the items to be fired. Through combustion chambers however, the wall losses increase and the same problems arise as with the combustion of a gas-air mixture in a burner outside the furnace.

The purpose of the invention is to use a different method to inadmissible high local firing and feed temperature with good thermal efficiency and to avoid high cross-sectional performance.

According to the invention, when dewatering, deacidifying and roasting bulk materials in the shaft furnace, to which the combustion air is at least partially fed from the outlet and the fuel, such as gas, oil mist or coal dust, in several horizontal directions Levels is introduced into the furnace, proceed so that the fuel introduction levels are alternately charged with the fuel.

Among other things, this method brings the advantages of the material being fired To protect from overheating and to achieve an evenly fired product that To protect oven lining from local overheating and thus a longer service life to enable, furthermore, to keep the performance of the furnace as high as possible without the aforementioned tasks are neglected, and the combustion of fuels, which are otherwise not used in the shaft furnace because of their high calorific value, e.g. B. heating oil, natural gas or coal dust to allow.

The following is a furnace with two fuel inlet levels and reference is made to lime burning without thereby limiting the invention.

According to a set program, the burn zone should move up and down and heat the item to be fired to a maximum permissible temperature, which is then carried out can post-deacidify down to a minimum temperature for limestone of around 820 ° C. The deacidification zone is therefore fixed.

The distance between the levels depends on the grain size of the material to be fired and after the fuel and the burnout route. The distance is generally not be smaller than 1 m and not larger than 3 m. Generally there is a distance of 1.50 m most expedient.

When the lower level of fuel introduction is working, the upper is out of order and vice versa. Switching on begins when the piece temperature has dropped to the lower deacidification limit and ends when it comes close the sintering limit has risen, which is around 1150 ° C depending on the contamination. Then it is switched. The time interval is through trials for each grit and to determine the chemical composition of the material to be fired and then either of Hand, but better stop automatically.

One embodiment of the invention consists in a portion of the combustion air to be introduced into the furnace in a cold or warm state above the gas inlet levels, preferably above each gas inlet. But then it is advisable to adjust the distance between the To enlarge fuel introduction levels, e.g. B. to 3 to 6 m Eliminate the lack of air at the edge of the furnace, and above the individual fuel inlet levels Extend the flame and lower its temperature by initially only part of the Combustion air from the cooling zone hits the fuel directly and the the remaining part of the combustion air is only supplied from the outside later.

If there are several fuel inlets immediately above the upper one At the fuel level, the flame should be as hot and short as possible. Therefore it is useful to provide the secondary air supply immediately above the top level, especially since there the hardly deacidified lime eagerly absorbs heat.

In all embodiments of the invention, the fuel has to be abandoned directly into the furnace the advantage that the high temperature losses of the pre-combustion chambers omitted and that there is no need for exhaust gas or steam or other temperature-lowering Agents that are otherwise supplied to the combustion chambers to use. With combustion chambers the chemically bound heat of the fuel is mostly converted into sensible heat converted, which, when massaged, hits the material to be burned which is in front of the combustion chamber mouths lies. On the other hand, when the fuel is directly fed into the furnace, the heat still chemically bound distributed over a larger area and can there after mixing be released more evenly with air on a larger part of the material to be fired.

With the method of feeding the fuel periodically in several levels, Another advantage is connected, which is an increase in performance without an increase in temperature of the material to be fired. Every time the lower fuel inlet level is switched off is, the air that rises from the cooling zone and depending on the thermal Efficiency is heated to about 400 ° C there, by the lime which is over g20 ° C continue to heat in the lower part of the burning zone so that in the upper part of the burning zone the calorimetric temperature can rise without damaging the material to be fired and the feed possible are. The proposed supply of part of the combustion air Above the fuel inlets can also be used during the shutdown of the lower Fuel introduction level is maintained so that the temperature of the material to be burned in the lower part of the combustion zone is not lowered as much by rising air. This separate air supply is therefore not only used to generate a mild one Flame in the lower part of the burning zone and an increase in the burning zone, but favors the subsequent deacidification of the lime in a harmless temperature range.

In the drawings, as an example, a furnace according to the invention is schematically illustrated shown, namely in F i g. 1 shows a longitudinal section through the furnace and in FIG. 2 a section according to 1-I of FIG. 1.

This explains the case of limestone burning.

The furnace shaft is divided into a cooling zone K, a combustion zone B and a lower combustion zone B2, an upper combustion zone and the preheating zone B 1 V in accordance with F i g.1. There are two alternately operated fuel introduction levels. The lower level of fuel introduction is labeled II, the upper level with I. The deacidification zone E essentially coincides with the sum of the areas of both combustion zones. The extraction of air from the cooling zone K and its introduction between the two fuel introduction levels is indicated by the dashed line Lug, its introduction above the upper fuel introduction level by the dashed line Lu 1 bd. In Fig. 2, the fuel inlets 1 to 8 are shown.

When burning limestone, which is shown here as an example the furnace is operated roughly as follows: In the lower fuel inlet level II fuel is fed in until the temperature of the material to be fired and the food reaches the has fully or approximately reached the permissible maximum. Then the fuel supply moved to level I. When the temperature of the fuel is in the lower part of the deacidification zone has dropped again, although it should not drop below about 820 ° C again the fuel supply relocated to level II, etc. The switching periods can vary within a wide range. They will be useful for every furnace and each item to be fired is specially determined and specified. You can e.g. B. between about Last 10 minutes and several hours.

Claims (6)

Claims: 1. Process for dewatering, deacidifying and roasting of bulk materials in the shaft furnace, which the combustion air at least partially from Discharge supplied and the fuel, such as gas, oil mist or coal dust, in several horizontal levels is introduced into the furnace, characterized in that the fuel introduction levels are alternately charged with the fuel. 2. The method according to claim 1, characterized characterized in that above a fuel introduction level or above several A part of the combustion air is introduced from outside. 3. Procedure according to Claim 2, characterized in that the part of the combustion air to be introduced from the outside is removed from the cooling zone in a preheated state. 4. Procedure according to one of the preceding claims, characterized in that with the help of the lowermost Fuel introduction level the fuel and feed temperature is preferably brought quickly to or approximately to the permissible maximum, whereupon the fuel supply is terminated in the lower level and by one at a distance from it higher level is started, after which the lower combustion zone has cooled down the fuel supply is terminated through the upper level and again through the lower fuel introduction level is heated. 5. Shaft furnace for performing the method according to one of the claims 1 to 4, in which several horizontal fuel introduction levels at a distance from one another are provided, characterized by one or more switching devices with which the fuel supply periodically alternating through the different fuel introduction levels can be steered. 6. Shaft furnace according to claim 5, characterized by air inlets above one or more fuel inlet levels. Documents considered: German Patent No. 100 864; Austrian patent specifications No. 198 664, 130373.