DE3719644A1 - Method of combusting fuels as well as combustion installation - Google Patents

Abstract

In a combustion installation, the fuels are first comminuted and subsequently dried before they reach the combustion chamber. The drying heat is extracted from the combustion installation itself and the heat arising on the separation of moisture and fuels is supplied to the energy circuit of the combustion installation again, the combustion air being heated in a heat exchanger. A further energy recovery takes place by the dried comminuted fuels having a raised thermal value. The novel combustion installation thus makes possible for the first time the economical use of regenerable raw materials as moist fuels.

Description

The invention relates to a method for burning of fuels (biomass) in a combustion plant ge according to the preamble of claim 1, and also the invention is concerned with a combustion plant ge to carry out the procedure.

As is well known, incinerators are considerable Extent used to generate energy from the heat of combustion to create. This energy can be referred to as thermal energy District heating system can be supplied and next to it the energy is also used to go through turbi generate an electrical current. In the usual way becomes fresh through the combustion as a heat medium  steam (superheated steam), which is a heating circuit run or a turbine is supplied. At the Ener casting conversion results from live steam steam with lower energy content that with its Residual energy is supplied to a capacitor in which chem water arises that then heated up again that can.

In view of the existing large energy requirements the energy problem can be solved with the usual energy carriers such as coal and oil are no longer satisfied solve the problem. One of the main causes is here at the relatively unfavorable efficiency of burning Power generation plants. In an effort one is therefore tapping into new energy sources already encountered the so-called "gentle energy" for whom the term "biomass" is used, which are used as fuel should. These are energy sources such as for example garbage, wood, straw, grass or sewage mud etc., i.e. renewable raw materials that are available in large quantities.

However, the importance of gentle energy still significantly overestimated today because of their share  of energy generation is comparatively low and is only a few percentage points. This is due to the fact that the gentle energy assigned fuels in practice only with a very poor efficiency for energy generation let it draw. Under economic ge the gentle energy therefore still plays a role not matter because the previous usual energy carriers such as coal and oil despite their limited Amount are even cheaper.

On the other hand, there is no doubt that the Verwen from gentle energy to substantial economist could lead to economic advantages. This applies ins special for the field of agriculture, the would easily be able to ener appropriate The bearer of gentle energy in practically inexhaustible quantities in the form of renewable raw materials to provide. Nevertheless, this comes Advantage but as I said not to bear, because the Power generation with the gentle energy still with a very poor efficiency, i.e. with significant costs.

This is where the invention intervenes, which undermines the task  de lies, a method for burning fuels for the purpose of generating energy, wel the economic use of biomass or of gentle energy. In addition, by the invention an apparatus for performing the Procedure are specified.

This task is solved by the in the waiter Concept of claim 1 called method the characteristics given in the characterizing part, and with regard to the incinerator Object by the features of claim 11 solved.

The basic idea of the invention is first shred the fuels and then eating - which is of particular importance - too dry before the fuels are led to the combustion chamber will. These features make it possible for the first time also moist fuels for use in combustion systems to use.

A particular advantage is that the for heating the fuels after they have been broken up Necessary thermal energy or digestion to  one is taken from the incinerator itself, and that it is provided on the other hand, which in the dry heat generated back into the energy cycle to the incinerator. The latter is done both by preheating the combustion air as well as the one heated during drying Fuel itself, because the heated fuel leads to an increase in the calorific value.

The important aspect of the invention is that for moist flammable substances in a new way a possible use for energy production is created in an incinerator that also compared to known incinerators has much higher efficiency. Leave with it moist flammable substances are also exposed to introduce the scientific aspects of energy generation, what has so far failed because the moisture thermal energy not usable in the fuels Shape of the condensate heat in the flue gas, so that at most a combustion of moist burning substances in special systems with high economic Costs could be considered.

So while so far an economic energetic  Always use moist fuels with moisture Erfin has failed in the fuels through the measures of shredding the burning fabrics in such a way that they are dryable, and a separation by the subsequent drying of water and fuel mass before, being for this Separation practically no additional energy required is because on the one hand the drying energy of the ver incinerator itself, and because other on the other hand, the separation of water and fuel heat energy of the combustion system is fed again. The result is as Another advantage that the exhaust air in the new Ver incinerator is completely dry, and that none Condensate heat is carried away unused in the flue gas.

The invention has in economic terms engrave one especially for agriculture the advantage, since it is now possible to grow Raw materials that are practically unlimited Are available for commercial exploitation to supply for energy production. So far, in the Represent experts in the opinion that grow back en Only allow raw materials to be used economically if the prices of the usual energy sources like earth  oil to rise significantly. Let against it the renewable raw materials in the invention especially from an economic point of view use in part, being cheaper than oil or Hard coal are classified.

The latter point of view is above all essential for developing countries, where the energy prices for the oil to be imported or are relatively high for the coal to be imported. On the other hand, there are renewable ones in these countries Raw materials readily available, which according to the invention inexpensively for power generation infuse after the high water content of this Fuels no meaning when using the invention tung has more.

The invention thus easily creates the possibility To use corn or damp grass as fuel and, based on calculations, it can be proven that in this case the energy price is not higher than for heating oil, hard coal, lignite or lignite lebriquet lies, and that the energy price of wood is even far below.  

The possibility created by the invention of Use of renewable raw materials for energy generation advantageously contributes to the overproduction in the Agriculture under economically favorable ge reduce points of view. Otherwise you can also Sewage sludge or household waste in an advantageous manner for use the new incinerator.

Further expedient configurations and advantageous Further developments of the invention result from the Claims, the description and the drawing.

For a better understanding, the invention will follow based on the From shown in the drawing examples of management explained in more detail. Show it:

Fig. 1 is a schematic principle circuit diagram of a combustion system according to a first embodiment of the invention, and

Fig. 2 is a schematic principle circuit diagram from another embodiment of the invention.

In Fig. 1 as a whole with the reference numeral 10 be designated combustion system is used to generate live steam, which can supply a variety of heating systems in a district heating system.

The incinerator 10 includes a crushing device 14 where the fuels 12 are broken down. The comminuted fuels 12 then arrive at a drying installation 16 , to which a fuel bunker 22 and a combustion chamber 24 connect.

The drying system 16 is surrounded by a pipeline system 18 , from which a part of the heated fresh steam - for example 10% - is supplied from a distributor 36 via a pipeline 38 . From the piping system 18 , drying heat is given off to the comminuted fuels 12 within the drying system 16 , and the steam which cools down is conducted via a pipeline 40 to a condenser 32 .

On its one side facing the fuel bunker 22 , the drying system 16 is fed 42 flue gas from a waste heat boiler 26 via a flue gas line. The other side of the drying system 16 is connected via a pipeline 44 to a condensate heat exchanger 20 , to which warm air is also supplied from the fuel bunker 22 via a pipeline 52 .

The combustion air is fed into the combustion chamber 24 via a fresh air line 46 , the fresh air line 46 running through the heat exchanger 20 , which heats the fresh air. Via a condensate line 48 , the condensate of the heat exchanger 20 is removed and collected, and via a Kaltluftlei device 50 , the exhaust air is removed for cleaning. For this purpose, the cold air can be passed through a biofilter to absorb the aromas released in the drying process.

From the waste heat boiler 26 extends the fresh steam line 28 , which is partially passed through the combustion chamber 24 . The live steam is thus heated in the boiler 26 and in the combustion chamber 24 and reaches a consumer 30 , for example a district heating system.

From the consumer 30 , the exhaust steam is returned to the condenser gate 32 and from there via a pipe 34 back to the waste heat boiler 26 , whereby the circuit is closed.

The live steam flowing to the consumer 30 has a temperature of approximately 540 ° C., about 90% of the steam quantity reaching the consumer 30 via the already mentioned distributor 36 , while the remaining 10% are fed to the piping system 18 in order to reduce the fuels 12 to dry. The condensate flowing back in the pipe 34 has a temperature of approximately 25 ° C., while the temperature of the flue gas supplied to the drying system 16 via the pipe 42 is approximately 170 ° C. Inside the fuel bunker 22 , the temperature is about 180 ° C, and the fresh air heated by the heat exchanger 20 has a temperature value of about 150 ° C.

The incinerator 10 described so far is particularly suitable for the economical combustion of moist fuels, for example corn. After the comminution, the moist fuels 12 are dried in the drying system 16 , ie here he separates water and dry fuel mass, this process not taking place at the expense of the energy contained in the moist fuel 12 . The moisture which separates during drying is heated by the flue gases supplied via the flue gas line 42 , and the resulting wet steam with flue gas reaches the heat exchanger 20 via the line 44 . There, the heat of the wet steam with flue gas is used to heat the combustion air led by the fresh air line 56 ge. In addition, the warm air of the fuel bunker 22 can also be led to the heat exchanger 20 in order to heat the fresh air.

Completely dry and already preheated fuels reach the combustion chamber 24 , and the combustion air has also already been heated. In other words, this means that the energy required for the drying system 16 for drying the comminuted fuel 12 is obtained without external additive energy, since the energy which arises during drying is supplied to the energy cycle of the combustion system 10 and since the dried fuel fabrics have a high calorific value.

In the exemplary embodiment according to FIG. 2, the combustion system 10 is designed for generating electrical energy with the aid of a steam turbine 60 which drives a generator 62 . For corresponding Tei le in Fig. 2, the same reference numerals have been used as in the incinerator in Fig. 1.

Also, in the combustion system of FIG. 2, the damp fuels are crushed and drying plant in the Trock 16 dried. The turbine 60 leaves de and at about 320 ° C still relatively hot exhaust steam is first led via a pipe 56 to a pipe system 58 which surrounds the fuel bunker 22 and additionally heats it up.

From the pipeline system 58 , the exhaust steam also reaches the pipeline system 18 of the drying system 16 via the pipeline 38 . Furthermore, the still hot exhaust steam is branched off from the pipeline system 58 via a white pipeline 68 and supplied to an air preheater 72 designed as a heat exchanger. The exhaust steam passes through a pipe 70 and pipe 40 to a condenser 66 .

The air flowing through the fresh air line 46 to the combustion chamber 24 is therefore heated twice here, namely by the heat exchanger 20 on the one hand, and on the other hand by the air preheater 72 .

The incoming steam at the condenser 66 still has a temperature of the order of about 250 ° C to 300 ° C, and because of this energy content still present, an additional consumer 64 (cogeneration) can optionally be provided, for example in the form of a heater.

In Fig. 1, the dashed ge drawn connecting line 54 between the Rohrlei lines 46 and 42 may be made. This makes it possible to branch off part of the heated combustion air for drying the fuels 12 .

Claims (16)

1. Process for the combustion of fuels (biomass) in a combustion plant for the purpose of generating energy, the fuels being supplied to a combustion chamber, the flue gases being produced during the combustion, and a heat medium, in particular fresh steam, resulting from the heat produced or heat transfer oil, which is fed to a heating circuit or an energy converter, characterized in that the fuel ( 12 ) is first crushed and then dried by means of drying heat in a drying system ( 16 ) before the fuels ( 12 ) to the combustion chamber ( 24 ) arrive, and that the drying heat of the incinerator ( 10 ) itself is removed and fed back to it. 2. The method according to claim 1, characterized records that the drying heat from the flue gas and partially obtained from the heated heating medium becomes. 3. The method according to claim 1 and / or 2, characterized in that heat is obtained from the wet steam generated during drying of the comminuted fuels ( 12 ) with flue gas, and that the combustion air ( 24 ) supplied combustion air is heated by this heat. 4. The method according to any one of claims 1-3, characterized in that the heat from the wet steam in a condensate heat exchanger ( 20 ) is recovered, and that water formed (Kon densat) is collected. 5. The method according to claim 1 and / or 2, as by in that is obtained from the resulting when drying the comminuted fuels (12), wet steam (12) with flue gas heat, and that the flowing back from the drying plant (16) heat medium this heat is heated. 6. Method according to one of the preceding An sayings 1-5, characterized in that as a focal substances renewable raw materials such as wood, corn, grass etc. can be used. 7. Method according to one of the preceding An sayings 1-5, characterized in that as a focal sewage sludge is used. 8. Method according to one of the preceding An sayings 1-5, characterized in that as a focal household waste is used. 9. The method according to any one of the preceding claims 1-8, characterized in that the zererkern and dried fuels ( 12 ) an insulated th fuel bunker ( 22 ) are fed from where they reach the combustion chamber ( 24 ). 10. The method according to claim 9, characterized in that the fuels ( 12 ) in the fuel bunker ( 22 ) are heated by the heat medium. 11. Incinerator with a combustion chamber, a supply for combustion air, a discharge for flue gases and a discharge for the heating medium heated by the combustion, in particular live steam or heat transfer oil, characterized in that the combustion system ( 10 ) has a comminution device ( 14 ) for the Fuels ( 12 ) and a drying system ( 16 ) for the comminuted fuels ( 12 ). 12. Incinerator according to claim 11, characterized in that the drying system ( 16 ) in the manner of a heat exchanger with a piping system ( 18 ) is surrounded, in which the heating medium can be introduced via an actuator organ. 13. Incinerator according to claim 11 and / or 12, characterized in that the interior of the drying system ( 16 ) is connected on one side to the discharge line ( 42 ) for the flue gases. 14. Incinerator according to claim 13, characterized in that a condensate heat exchanger ( 20 ) is provided, the input of which is connected to the other side of the interior of the drying system ( 16 ). 15. Incinerator according to claim 14, characterized in that the supply for combustion air is formed by a through the condensate heat exchanger ( 20 ) guided fresh air line ( 46 ). 16. Incinerator according to one of the preceding claims 11-15, characterized in that an insulated fuel bunker ( 22 ) is arranged in front of the combustion chamber ( 24 ) and that the fuel bunker ( 22 ) can be heated by the heating medium.