DE2710205A1 - Roasting lime in shaft furnace heated by burning rubbish - with automatic addn. of other fuel depending on heat content of rubbish - Google Patents

Abstract

Lime is roasted in a shaft furnace using recirculated gases heated by the burning of rubbish with variable heat contents, and also by fuels with constant heat content, where fuels are dosed according to the heating value of the gases obtd. from rubbish. Gas from the rubbish is pref. fed only to the upper burner plane and gas from fuel only to the lower burner plane; alternatively, both gases may be fed to plane and only gas from fuel to plane. The rubbish is pref. the major fuel, and pref. includes rubber from used tyres. Gas temp. and compsn. and/or calculations can be used for dosing fuel; and a ring shaft furnace is pref. used. Many types of domestic waste, cut old tyres and plastic cuttings can be used as fuels, but a constant prod. i.e. CaO is obtd. by adding fuel according to variations in fuel.

Description

Method for burning lime in a shaft furnace with

Recirculation gas system The invention relates to a method for burning limestone and / or other carbonate rock in a shaft furnace with a circulating gas system, whereby the combustion energy comes entirely or partially from waste materials how garbage and / or used tires are obtained.

The energy contained in such waste materials was previously either converted into steam or electricity after combustion or gasification or served as long-distance gas for purposes. The efficiency of the energy conversion was not particularly large in the systems built up to now. In lime kiln was with Experiments gained energy in this way, but without a convincing one Success was achieved. The use of waste gases obtained from waste in a lime kiln would have the particularly highly valued advantage that with itself continuously renewing lime an excellent means of binding environmentally harmful substances Substances are available, either in some cases even in the first place thermal recycling of waste permits or at least the restraint of pollutant emissions significantly simplified and investment and operation cheaper.

DOS 23 28 332 deals with a method for destroying waste by gasification in a gas generator, after which the gas e.g. the combustion chamber a lime or cement kiln and burned in it. Also is already the combustion of the generated gas in combination with an oil or pulverized coal combustion stimulated.

Already in the German patent application P 26 47 021.3 a method to operate a lime shaft furnace connected to a furnace for splitting old tires described, according to which the outside of a shaft furnace with a lack of air from the thermally decomposition products obtained from decomposed old tires with considerable amounts of soot fed to a lime shaft furnace and with the lower air of the Shaft furnace to be burned, so that a complete burn of the lime achieved will.

A disadvantage of using household waste obtained by pyrolysis Gas lies in its considerably fluctuating content of combustible components and thus in its different ensemble content. Can also be sorted by pre-sorting a large fluctuation in the supplied gas generated from household waste could not be avoided will. The calorific value of pyrolysis gas produced in this way varies between 800 to 3000 kcal / Nm3.

Due to the current state of the art, it was not foreseeable that with standard kilns in the lime industry a satisfactory use of energy Household waste and similar waste material is possible to get evenly burned To obtain lime.

The task was therefore to develop a method which it allows that which arises in the gasification of waste materials of various kinds combustible gas with different calorific values for burning lime in anyway to use a conventional type of shaft furnace and one just as evenly To achieve burnt lime, as it is when using e.g. oil, natural gas or generator gas uniform composition and a calorific value of 6000 to 10000 kcal / Nm will.

This task of burning lime in a shaft furnace was solved with a circulating gas system, in which, in addition to the waste products arising from the pyrolysis Thermal energy with different heat contents Fuels with a constant calorific value are used in that the fuel is dosed with a constant calorific value, in Dependence on the calorific value of the waste pyrolysis gas is added. In this way it is possible to reduce the wide range of fluctuations generated e.g. from household waste Pyrolysis gas in the production of high quality, evenly burnt lime to compensate.

The process of making it can be more conventional in any lime shaft kiln Carry out design, provided the shaft furnace is set up for circulation gas systems and has one or more burner levels.

There is a preferred embodiment of the method according to the invention therein1 that shaft furnaces with two burner levels are used, with that of waste pyrolysis The resulting gas is only given up on the upper burner level and in the lower one At the burner level, only fuel with a constant calorific value is used. This procedure ensures that the fuel gases are thoroughly mixed, which ultimately leads to evenly burnt lime.

Another way of giving up heating energy is to in the upper burner level only fuel with constant calorific value, i.e. To give up generator gas, natural gas or oil, combined in the lower burner level Use fuel with constant calorific value and gas from waste pyrolysis.

Finally, it is also conceivable to exclusively use the upper burner level rit fuel to send constant waizwer'es and the burners below only supply the gas that comes from waste pyrolysis.

It was now important to find a parameter for the amount of energy carrier with constant calorific value, the calorific value of which is higher than the calorific value of the Garbage pyrolysis originating gas to determine and in this way continuously the due the fluctuation range of the waste gas to compensate for excess or shortfall.

Such parameters presented themselves in the form of continuous energy content increases of the gas, ongoing measurements of the gas composition including ongoing quantity measurements or ongoing temperature measurements in the circulating gas or already in Pyrolysis gas of the waste materials. As a directly usable control variable for dosing of the energy source with constant calorific value was finally the temperature of the Recirculation gas detected, which is also the easiest to detect.

If the supply of pyrolysis gas fluctuates particularly strongly or if it is strongly changing gas composition may prove useful, not just one Use the parameter of the pyrolysis gas as a reference value, but the dosage constant energy content of the gas due to the integration of several parameters, such as the temperature and / or the heat content and / or the gas composition and / or the calorific value and / or the amount of gas and / or the gas pressure obtained Data.

Since the temperature of the circulating gas depends on the heat absorption capacity of the lime in the lowest part of the combustion zone depends on the heat absorption capacity of the Lime but also from it already in the upper parts of the lower combustion zone supplied heat. It was therefore found to be particularly useful to use the gases from the Waste pyrolysis preferentially to the burners of the upper level, the energy constant Heat content, i.e. oil or generator gas, the burners of the lower level of the ring shaft lime kiln to give up.

If there are special requirements for environmental reasons, this would have to be the case Gas for waste pyrolysis is fed to the lower burner level and the upper burner level the carrier of constant energy content are given up. The lime quality could possibly controlled by additional correction of the lime residence time.

Finally, there is also the option of introducing the Energy carrier constant energy content in the lower combustion chamber subject of the method according to the invention. The supply of, for example, oil or generator gas serves to compensate for any occasionally occurring lower levels caused by the pyrolysis gas. mmender Amounts of energy due to different hizwertoc.hwankung2n of the waste the heat content of the pyrolysis gas, for example higher than average in the case of gasification The supply of the generator gas is a proportion of paper, plastics or scrap tires throttled in the same wetness.

Due to the structural and procedural conditions of the Ring shaft furnace system, it is possible in this way, the limestone or lime evenly to apply heat and to obtain a lime that is always evenly burnt. The lime kiln can be operated continuously with the gas from waste pyrolysis plants provided the missing amount of energy indicated by the reduced circulating gas temperature by supplying a heat carrier with constant energy content such as generator gas, Natural gas or oil is compensated.

The present invention also makes a contribution to the general Strive to save high-quality energy, especially energy to be imported replace it with energy contained in waste. By adding crushed Bulky waste, scraps of used tires or plastic waste can reduce the calorific value before z.P. Household garbage Aufobessre and fluctuations in the energy supply are partially compensated.

The present invention further overcomes the prejudice accordingly Gases from the incineration or pyrolysis of household waste, etc. because of the large fluctuation range the calorific value of conventional fuels is not to be regarded as equivalent would be. The invention also shows that gases produced from these waste materials with regard to pollutant emissions or

-mrnission can be mastered in conventional factories.

Example: The procedure is explained in more detail using the following example explained. Figure 1 shows a section through a lime shaft furnace with a circulating gas system. This shaft furnace has five firing cones on two levels, one above the other evenly distributed, with the top and bottom staggered are.

The outer furnace jacket (10) and the inner cylinder (12) together form one Annular space (14) in which the heat transfer from the hot flue gases from the combustion chambers (16) and (16 ') takes place on the bulk material. The direction of flow of the gases is through Arrows indicated. The flue gases flowing down from the lower combustion chamber together with part of the lime cooling air rising from below form the circulating gas, which enters the inner cylinder (12) at (18) and via the circulating gas duct (20) the lower combustion chamber (16) is fed back.

The two gas streams forming the Urrw.älzgas are during the Oven operation kept largely constant in their amount. The temperature of the circulating gas is then determined by the temperature, not the one from the u.Leren Brannkdmmer downwardly flowing flue gas enters the inner cylinder at (18). Determining temperature but is the degree of deacidification with which the bulk material enters the lower combustion chamber area leaves and reaches the cocurrent zone with downward flue gas. With perfect With deacidified limestone, the endothermic reaction, the calcium oxide, is complete is no longer able to continue extracting heat from the flue gases. Increasing In contrast, the residual carbonate content causes the circulation temperature to drop and is the more to be expected, the lower the heat supply from the two combustion chambers is set.

The procedure now provides for the following: The two Fuels with different or constant calorific values are used in the combustion chambers abandoned in separate lines. For example, the fuel gas is from waste pyrolysis into the upper combustion chambers (16 '), the fuel with constant calorific value on the other hand introduced into the lower combustion chambers (16).

Fluctuations in the amount and calorific value of the pyrolysis gas have an effect according to the relationships described above on the temperature with which the circulating gas enters the inner cylinder (12) at (18).

A temperature sensor (22) attached at this point mediates the measured value to a control device (24), which it with a predetermined target value compares and, in the event of a discrepancy, sends a corresponding pulse to the control valve (26) passes on in the fuel line with a constant calorific value. In this way temperature fluctuations in the pyrolysis gas are compensated and the furnace receives the fuel energy that the limestone needs to deacidify at any point in time needed.

Another advantage of this method is that the amount of fuel the respective needs due to the different degrees of purity of the limestones this control device is automatically adapted.

Further possibilities are: a) at the outlet point of the circulating gas (28) to connect a gas analyzer (30) via a gas extraction nozzle, the the chemical composition of the circulating gas is continuously determined and depending on the specified Setpoint acts on the control valve (26); b) with one on the upper combustion chamber (16 ') installed calorimeter (32) continuously the calorific value and pressure, temperature and gas velocity to determine the energy content of the pyrolysis gas (34) and to the control valve (26).

Claims (11)

Method for burning lime in a shaft furnace with a circulating gas system in which, in addition to the pyrolysis of waste materials (garbage) resulting thermal energy with different heat content fuels with constant Calorific value are used, characterized in that the fuel with constant Dosed calorific value, depending on the calorific value of the garbage pyrolysis originating Gas is added. 2. The method according to claim 1, characterized in that in the upper Burner level only gas from the Nüllpyrolyse and in the lower burner level only fuel with constant calorific value is used. 3. The method according to claim 1, characterized in that in the upper Burner level only fuel with constant calorific value, in the lower burner level combines fuel with constant calorific value and gas from waste pyrolysis will. 4. The method according to claim 1 to 3, characterized in that as Fuel predominantly gases from waste pyrolysis are used. 5. The method according to claim 1 to 4, characterized in that the Garbage used tire rubber is added. 6. The method according to claim 1 to 5, characterized in that the Dosing of the fuel with constant calorific value via a circulating gas range The temperature measurement arranged in the shaft furnace takes place. 7. The method according to claim 1 to 5, characterized in that the Dosing of the fuel with constant calorific value via an evaluation of the gas analysis of the circulating gas takes place. 8. The method according to claim 1 to 5, characterized in that the Dosing of the fuel with constant calorific value by integrating the heat content, the temperature and / or further parameters according to claim 6 and / or 7 takes place. 9. The method according to claim 1 to 5 and one of claims 6 or 7, characterized in that the main amount of heat is a fuel with a constant Calorific value of 6000 to 10000 kcal / kg is taken. 10. The method according to claim 1 to 5, one of claims 6 or 7 and Claim 8, characterized in that a ring shaft furnace is used as the lime kiln is used. 11. The method according to claim 1 to 5, one of claims 6 or 7 and Claim 8, characterized in that the lime kiln is an inclined shaft kiln is used.