DE4438356C2 - Method and device for the two-stage combustion of gaseous or vaporous fuel - Google Patents

Description

The invention relates to a method and an apparatus for two-stage combustion of gaseous or vaporous fuel with downstream heat extraction.

Such methods and devices are from practice knows. The downstream heat extraction serves above all Things of heating or domestic water heating.

There are two fundamentally different types Procedural procedures, namely on the one hand the two-stage flames combustion and secondly the two-stage catalytic Ver burn.

In the case of two-stage flame combustion, efforts are made to keep the flame temperatures low in view of the NO _x formation. However, this is only possible to a limited extent, since otherwise the CO values rise too much. Flame stability also requires a certain minimum temperature. Overall, pollutant emissions cannot be reduced at will.

The flameless catalytic combustion works on low temperature level. For the complete conversion of methane fuels containing such high temperatures tures required that there be premature deactivation the catalysts can come. Their lifespan is demented speaking limited.

The invention has for its object in two-stage Ver burning the possibility of extremely low-pollutant working to create trouble-free long-term operation.

The method according to the invention is used to achieve this object characterized in that the two combustion stages after different reaction principles are operated, whereby a substoichiometric flame burning in the primary stage Heat extraction takes place while in the secondary stage  flameless catalytic combustion with excess air is carried out.

DE 35 03 413 C2 is a two-stage process Combustion process known in which a Flame combustion followed by catalytic combustion, however here the fuel becomes part of the first and Part fed to the second stage, the first stage works stoichiometrically or superstoichiometrically without heat extraction. So there are the above discussed disadvantages.

Furthermore, AT 387 643 B describes a method which uses a Fire chamber and a catalytic afterburner works, but it does not generate heat, but rather Pollutants are burned from a ventilation device should.

The invention is based on the finding that a catalytic cal combustion must work at high temperature if the fuel contains methane because of the high stocks energy of methane.

According to the methane is largely implemented in the primary stage, with a high proportion of CO and H₂ being produced because of the substoichiometric combustion. At the same time, heat is extracted from the primary stage, so that the temperature of the flame combustion can be kept low. The downstream secondary catalytic combustion no longer aims at the conversion of methane, but at the conversion of CO and H₂, whose activation energy is comparatively low. The temperature of the catalytic secondary stage can thus easily be kept below the limit which, when exceeded, entails the risk of deactivation of the catalysts. The service life of the catalysts is therefore not shortened. Since the secondary stage works with excess air, there is a complete combustion of the carbon monoxide. NO _x cannot develop due to the low working temperature.

Overall, the invention enables a trouble-free long-term combustion with extremely low pollutant formation.

Particularly favorable results can be achieved if the Air ratio of the primary stage to 0.5 to 0.95, preferably to 0.6 is set to 0.9 and if the stam from the primary level Gases secondary air is mixed in such an amount that  a total air ratio of 1.0 to 4.0, preferably of 1.05 to 1.8. The admixture of secondary air follows in such a way that a homogeneous, low set mixture temperature and thus no uncontrolled further gas phase reactions (oxidation of CO and H₂) possible are.

Preferably at least part of the primary stage decoupled heat and decoupled after the secondary stage heat is fed to a common heat transfer medium.

It is particularly advantageous to use part of the Pri to supply coupled heat from the secondary air. This increases the working temperature of the secondary stage only slightly Lich, but causes the secondary air bil no cold zones who can disrupt the operation of the secondary school.

In a development of the invention it is proposed that between additional heat extraction through the combustion stages is performed, this heat preferably also the ge common heat transfer medium is supplied. The additional Heat extraction also helps to control the temperature of the Keep secondary level low.

The gases emerging from the primary stage are preferred subjected to a catalytic NO reduction. The special one The advantage of this measure is that the primary stage emerging gases suitable reactants in excess contain, namely CO and H₂. Existing NO can thus verver be casually reduced. On this catalytic NO reduction can be omitted if already in the primary combustion zone ne approx. 15-30% of the heat of reaction from the combustion zone is coupled.  

The primary stage is preferably over during the start operated stoichiometrically, until the secondary level has reached its working temperature. The secondary air supply can already be set to the operating value the.

In an essential further development of the invention it is proposed that behind the secondary stage the CO content of the combustion gases is detected and that the primary level is overstoichiometric operation is switched if the CO content is impermissible increases. This serves to monitor the safety of the process. The primary stage can be operated by simple flame monitoring secured. This measure does not apply to flames loose catalytic combustion, as in the secondary stage takes place. For a catalytic one loaded with methane The combustion stage remains the only monitoring option Detection of the methane content in the exhaust gas. In contrast, the CO Determination according to the invention according to the current state of the Sensor technology much easier and more reliable. Above all Things fully serve their purpose, since they invent Secondary stage according to the invention is not fed with methane, son with carbon monoxide and hydrogen.

The invention provides a device for the combustion of gas or vapor fuel, with a primary combustion chamber, egg ner secondary combustion chamber and one of the secondary combustion chambers downstream main heat exchanger for a heat transfer medium medium, this device to solve the posed is characterized in that the primary combustion chamber as cooled flame combustion chamber is formed while the Sekun intestine combustion chamber is a flameless catalytic combustion chamber. With this device, those advantages are achieved that have already been explained above using the method.  

The primary chamber is preferably surrounded by a cooling jacket, which is connected to the main heat exchanger. The total together with the resulting heat is in one and the same heating or Process water circuit initiated.

It is advantageous between the primary combustion chamber and its Cooling jacket provided a secondary air duct. The decoupled heat is distributed to the secondary air and the cooling man tel, the secondary air being simultaneously convective heat transmitter acts.

It is particularly advantageous to use the combustion chamber as a jet tube, which intensifies the surrounding cooling jacket irradiated. The heat output of the primary combustion chamber can also can be increased in that a bed of ceramic body pern is arranged in the combustion chamber.

In a development of the invention it is proposed that between the primary and secondary combustion chambers have an intermediate heat exchanger is provided, which advantageously also with communicates with the main heat exchanger.

It is also advantageous to NO-Re the primary combustion chamber downstream catalytic converter.

A CO sensor behind the secondary combustion chamber provides a special ders advantageous feature because in this way a particular easy monitoring of catalytic combustion light becomes. Faults in the secondary combustion chamber have an effect as an increase in the CO content in the exhaust gas. The sensor speaks on it, it is sufficient to over the primary combustion chamber to switch stoichiometric operation to the failure of the Se to compensate for the secondary combustion chamber.  

Such combinations are also considered to be essential to the invention tions and sub-combinations of the features according to the invention, that deviate from the attached claims.

The invention is based on a preferred Aus example in connection with the enclosed drawing tion explained in more detail. The drawing shows in:

Fig. 1 shows schematically a flow diagram of the process;

Fig. 2 shows a section through an overall burner.

According to Fig. 1, a first mixing device 1 is provided, which, as indicated by arrows, gas and primary air are supplied. In the mixing device 1 , a homogenization of the mixture takes place simultaneously. The primary air ratio is set between 0.65 and 0.90.

From the mixing device 1 , the mixture reaches a first combustion stage 2 , in which substoichiometric flame combustion takes place. At the same time, as indicated by an arrow, heat is released. The flame is burned at a low temperature and therefore works extremely low in pollutants.

An NO reduction catalyst 3 is connected to the first combustion stage 2 . The reduction takes place with the reaction partners CO and H₂, which are available in abundance. With sufficient heat extraction in the primary combustion chamber, this catalyst stage can be dispensed with.

The combustion gases thus cleaned pass into an inter mediate heat exchanger 4 which, as indicated by an arrow, takes additional heat from the combustion gases and further reduces its temperature.

The combustion gases are then mixed in a second mixing device 5 - as indicated by an arrow - with secondary air. The amount of air is adjusted so that the total air number for the process is from 1.05 to 1.8. The secondary air is mixed in such a way that a homogeneous, low mixture temperature is set as quickly as possible, at which no oxidation of the CO and H₂ in the gas phase is possible.

The complete conversion finally takes place in a second combustion stage 6 , in which a catalytic combustion takes place. This takes place at temperatures at which deactivation of the catalysts is not yet to be feared. The temperature can be so low because the activation energies of carbon monoxide and hydrogen are low, much lower than the activation energy of methane.

The second combustion stage 6 is followed by a main heat exchanger 7 , which is used for heating or hot water. This heat transfer medium, the decoupled heat from the intermediate heat exchanger 4 and from the first combustion stage 2 is supplied.

During the start, the first combustion stage 2 works via stoichiometric, and until the second combustion stage 6 has reached its operating temperature. The secondary air is set to the operating value from the start.

As soon as faults occur in the second combustion stage 6 , these are recognized by a CO sensor working in the combustion exhaust gas. The sensor switches the primary stage 2 to overstoichiometric operation.

In a departure from the process illustrated and described, the reduction catalytic converter 3 and / or the intermediate heat exchanger 4 can be dispensed with, depending on the circumstances. The heat extracted in the primary stage 2 can also be used independently of the main heat exchanger 7 and the specified air numbers can be set higher or lower within the scope of the invention. The catalysts can be honeycomb or bulk catalysts.

Fig. 2 shows a working with flame combustion primary combustion chamber 8 , which is designed as a jet pipe and consists of Kera mic or steel. As ceramic materials AL₂O₃, SiC or SiSiC come into question. The primary combustion chamber 8 is charged with a substoichiometric mixture which burns on a burner plate 9 . The combustion exhaust gases gelan conditions in a mixing zone 10 and mix there with secondary air, which is fed through a secondary air duct 11 . The mixture is set to an over-stoichiometric total air ratio and then passes into a catalytically working secondary combustion chamber 12 . This is where the remaining conversion of the carbon monoxide and hydrogen generated in the primary combustion chamber takes place. Both combustion chambers work at low temperatures and are therefore extremely low in pollutants.

The main heat exchanger 7 connects to the secondary combustion chamber 12 . This includes a cooling jacket 13 , which simultaneously forms the outer wall of the secondary air duct 11 . Heat is also extracted from the primary combustion chamber 8 . This reaches partly in the secondary air and partly in the cooling jacket 13 , the latter by radiation and convection. To increase the heat emission, the primary combustion chamber 8 can contain a bed of ceramic bodies, for example in the form of balls, cylinders, Raschig rings and the like.

In a departure from the embodiment shown, the device according to FIG. 2 can also be provided with an intermediate heat exchanger and with an NO reduction catalyst. Pt, Pd, Rh, Ir, Ru, N₂O, CeO, CuO and combinations of these substances come into question as materials for the latter. These materials are also preferably used for the catalyst of the second combustion stage.

Otherwise, the arrangement can also be made such that the heat coupled out of the primary combustion chamber 8 reaches the cooling jacket 13 completely.

Claims (19)

1. A method for the two-stage combustion of gaseous or vaporous fuel with downstream heat extraction, characterized in that the two combustion stages are operated according to different reaction principles, with a substoichiometric flame combustion with heat extraction taking place in the primary stage, while in the secondary stage flameless catalytic combustion with excess air is carried out. 2. The method according to claim 1, characterized in that the air ratio of the primary stage to 0.5 to 0.95, preferably to 0.6 to 0.9 is set. 3. The method according to claim 1 or 2, characterized net that the gases originating from the primary stage secondary air is added in such an amount that there is a total air ratio from 1.0 to 4.0, preferably from 1.05 to 1.8. 4. The method according to any one of claims 1 to 3, characterized characterized in that at least part of that from the primary decoupled heat and that after the secondary stage decoupled heat supplied to a common heat transfer medium leads. 5. The method according to any one of claims 1 to 4, characterized characterized in that part of the decoupled from the primary stage heat is supplied to the secondary air. 6. The method according to any one of claims 1 to 5, there characterized in that between the combustion stages additional heat extraction is carried out.   7. The method according to claim 6, characterized in that the heat released between the combustion stages common heat transfer medium is supplied. 8. The method according to any one of claims 1 to 7, characterized characterized in that the gases emerging from the primary stage be subjected to a catalytic NO reduction. 9. The method according to any one of claims 1 to 8, characterized characterized in that the primary stage during startup about is operated stoichiometrically. 10. The method according to any one of claims 1 to 9, characterized characterized in that behind the secondary level the CO content of Combustion gases are detected and that the primary stage overstoichiometric operation is switched when the CO Salary increases inadmissible. 11. Device for burning gaseous or vaporous fuel, with a primary combustion chamber and a secondary combustion chamber and with a secondary combustion chamber connected downstream main heat exchanger for a heat transfer medium, characterized in that the primary combustion chamber ( 8 ) is designed as a cooled flame combustion chamber, while the Secondary därbrennkammer ( 12 ) is a flameless catalytic combustion chamber. 12. The apparatus according to claim 11, characterized in that the primary combustion chamber ( 8 ) is surrounded by a cooling jacket ( 13 ) which is in communication with the main heat exchanger ( 7 ). 13. The apparatus according to claim 12, characterized in that a secondary air duct ( 11 ) is provided between the primary combustion chamber ( 8 ) and the cooling jacket ( 13 ). 14. Device according to one of claims 11 to 13, characterized in that the primary combustion chamber ( 8 ) is designed as a jet tube. 15. The device according to one of claims 11 to 14, characterized in that the primary combustion chamber ( 8 ) contains a bulk device made of ceramic bodies. 16. The device according to one of claims 11 to 15, characterized in that between the primary and the secondary därbrennkammer ( 8 , 12 ) an intermediate heat exchanger is provided. 17. The apparatus according to claim 16, characterized in that the intermediate heat exchanger with the main heat exchanger ( 7 ) is in communication. 18. Device according to one of claims 11 to 17, characterized in that the primary combustion chamber ( 8 ) is followed by an NO reduction catalyst. 19. Device according to one of claims 11 to 18, characterized in that the secondary combustion chamber ( 12 ) is followed by a CO probe.