EP1524473A1 - Process and device to burn fuel - Google Patents

Abstract

Process for combusting fuel in a fuel chamber (12) comprises mixing fuel and combustion air in front of the inlet to the fuel chamber to avoid self ignition, feeding a first part (36) of the mixture (34) so that it circulates in the combustion chamber, feeding further fuel into the circulation flow (46) of the first part of the mixture until heating to ignition conditions has been achieved, and feeding a second part (38) of the mixture into the combustion chamber so that it is mixed with a hot fuel gas (50) removed from the circulation flow, heated and burned up to its exit from the combustion chamber. An independent claim is also included for a device for combusting fuel in a combustion chamber. Preferred Features: The fuel and the combustion air are mixed so that the ratio of combustion air to fuel lies above the average air/fuel ratio of the combustion in the combustion chamber.

Description

The invention relates to a method and a device for Combustion of fuel in a combustion chamber.

The classic method of converting fuel energy in heat is the oxidation or combustion of liquid or gaseous fuel with an oxidant such as for example, atmospheric oxygen. In today's, heavily loaded Burning systems generally has the problem that this for very low emissions, especially low NOx emissions are to be interpreted. The combustion systems should a stable and complete throughout the operating range Allow combustion and thereby relatively low maintenance and work cost-effectively. To get around this problem are known, combustion systems are known in three groups be divided:

So-called standard low-NOx systems are with a premix of fuel and combustion air before entering one Provided combustion chamber. Inside the combustion chamber will be below a forming flame stabilizes and the oxidation reaction controlled by it. Due to remaining Blends occur locally within the combustion chamber high temperatures, resulting in an undesirably high NOx emission being able to lead. Therefore, in standard low-NOx systems the flame is usually primarily aerodynamically stabilized, whereby hot combustion gases are recirculated, so that they mix with the mixture entering the combustion chamber Fuel and combustion air react. The aerodynamic stabilization is supported by the use of hot support flames (so-called piloting), leading to further inhomogenization the temperature distribution in the combustion chamber being able to lead. Such an inhomogeneous temperature distribution can be an additional source of nitric oxide be. It is therefore common for standard low-NOx systems the primary NOx emissions from a catalytic Emission control can be lowered.

The field of application of catalytic combustion systems is currently limited so that, for example, for high-temperature combustion systems, such as. stationary gas turbines state-of-the-art Type, no catalytic burns are used can. Only in smaller stationary gas turbines become catalytic Combustion systems already used.

For industrial combustion systems are so-called Flameless Oxidation Burner known, as for example in EP 0 463 218 B1 are described. In these combustion systems Combustion air is preheated by means of the exhaust gas and in a Radial edge region of a combustion chamber fed with a high pulse. In the center of the combustion chamber is separately a fuel gas injected. The preheated combustion air mixes in the edge area the combustion chamber with recirculating exhaust and inside with the separately supplied fuel gas.

The invention is based on the object, a method and a device for burning fuel in one Combustion chamber in particular for gas turbines to create in which a stable and complete combustion as well as distinct Reduced NOx emissions can be achieved.

The object is according to the invention with a method for Burning of fuel dissolved in a combustion chamber, at the fuel and combustion air before entering the combustion chamber be mixed while avoiding auto-ignition, a first part of the mixture is introduced into the combustion chamber is that it circulates in the combustion chamber, in the Circulation flow of the first part of the mixture further Fuel is supplied until a warm up to ignition conditions guaranteed, and at least a second part the mixture is introduced into the combustion chamber, that he is with an outflow from the circulation flow, hot fuel gas mixes, heats up and up to his Exit from the combustion chamber burns. The task is further comprising a device for burning fuel in a combustion chamber dissolved, with a mixing device for mixing of fuel and combustion air before entering the Combustion chamber, avoiding auto-ignition, a first Mixture introduction device for introducing a first part of the mixture into the combustion chamber, such that the first part of the mixture circulates in the combustion chamber, a fuel introduction device for supplying further fuel into the circulation flow of the first part of the mixture, until a warm-up to ignition conditions would be ensured, and at least one second mixture introduction device for Introducing at least a second part of the mixture into the combustion chamber, such that the at least one second part of the mixture with a flowing out of the circulation flow, hot fuel gas mixes, heats up and up burns out of the combustion chamber.

According to the invention, a first quantity of fuel (e.g. Fuel gas 1) with combustion air before entering the combustion chamber premixed while avoiding autoignition. In the later reaction of parts of this mixture is a comparatively low temperature level, which is lower as the mean temperature level of comparable Combustion reactions. The burning of this part of the Mixture therefore leads to a relatively low NOx formation. The mixture of fuel and combustion air is according to the invention so introduced into the combustion chamber that a first part of the mixture is circulated in a recirculation vortex and at least a second part of the mixture itself with the effluent from the vortex hot exhaust gas or fuel gas mixed. By mixing with the hot exhaust gas is this part of the mixture is heated in sufficient form and burned to the combustion chamber outlet. A separate pilot in conventional form, however, according to the invention avoided and on aerodynamic stabilization measures by swirl generator can also be dispensed with.

By the inventive addition of the remaining fuel in one or more further stages (s) (for example fuel gas 2) so much energy is provided in the recirculation vortex, that a warming of the entire air / fuel mixture would be guaranteed on ignition conditions or until ignition conditions are present. The further fuel is admixed according to the invention such that a homogeneous Interference in the fuel gas at low temperature level he follows. In this way, according to the invention temperature peaks avoided within the combustion chamber. A special low NOx formation from this area of the reacting Fuel gas flow is the result.

In an advantageous embodiment of the invention Procedure, the fuel and the combustion air before a Entrance to the combustion chamber mixed so that the ratio combustion air to fuel above the average air / fuel ratio combustion in the combustion chamber lies. By the inventively high air / fuel ratio becomes a comparatively low temperature level ensures that NOx formation is reduced.

The device according to the invention can be particularly advantageous be configured by the first and / or the second Part of the mixture (and / or other parts in a multi-stage Fuel addition) from fuel and combustion air a centrally disposed in the combustion chamber body introduced becomes. In such a central Zuströmkörper arranged the first and / or the second mixture-introduction device. The inventively desired circulation flow of the first part of the mixture and the introduction of the second part of the mixture in outflowing, hot fuel gas can then be relatively easily realized fluidically become.

A central inflow body for the first and / or the second Part of the mixture of fuel and combustion air offers further advantageously the possibility that a device for Introducing liquid fuel integrated into the combustion chamber becomes. A centrally arranged mixture introduction device is further characterized by the flowing in her mixture of fuel and combustion air cooled, whereby the mixture minimally heated becomes. The heating has a further homogenization of the temperature level within the circulation flow according to the invention result.

The circulation flow itself is advantageous according to the invention in a peripheral region of the combustion chamber, i. in one formed radially outer portion of the combustion chamber. One thus formed recirculation vortex forms advantageous the basis for the most homogeneous possible interference of further fuel into the combustion chamber.

Moreover, it is inventively advantageous if the Combustion chamber is designed substantially cylindrical and the first part of the mixture of fuel and combustion air substantially is introduced radially into the combustion chamber. By the radial introduction of the first part of the mixture is the inventively desired circulation flow excited and maintained. Alternatively, an annular combustion chamber provided with a correspondingly designed fuel supply be.

In contrast to a radial introduction of the first part the mixture of fuel and combustion air is the other Fuel advantageously substantially axially into the combustion chamber brought in. Such addition of residual fuel (Fuel gas 2) in the recirculation vortex, provides the required Amount of energy ready, thus the desired warming up of the entire air / fuel mixture to ignition conditions would be guaranteed. Another advantage of an axial Introducing the other fuel is that the supplied more fuel at the same time also for cooling the combustion chamber end wall contributes and thereby the further Fuel is slightly preheated.

To the device according to the invention and thus executed Making procedures comparatively easy becomes the first and the second part of the mixture of fuel and Combustion air advantageous as a common stream into the combustion chamber introduced and split only within the combustion chamber.

When introducing one or both parts of the mixture from fuel and combustion air can advantageously particularly adapted Nozzles are used to allow the respective parts of the mixture particularly targeted and dosed in the circulation flow reach. Thus, the circulation flow according to the invention and operated the combustion produced stable can be beneficial in it per unit of time about 5% to 25%, in particular between about 10% and 20%, the total fuel supplied during a unit time Combustion air mass (total gas mass) recirculated.

• Fig. 1 einen Längsschnitt eines Ausführungsbeispiels einer erfindungsgemäßen Vorrichtung zum Verbrennern von Brennstoff in einer Brennkammer.

Hereinafter, a preferred embodiment of the method according to the invention and the inventive apparatus for burning fuel in a combustion chamber will be explained in more detail with reference to the accompanying schematic drawing. It shows:

• Fig. 1 is a longitudinal section of an embodiment of an inventive device for combusting fuel in a combustion chamber.

In Fig. 1 is a device 10 for burning fuel in a combustion chamber in the form of a burner for a stationary gas turbine shown. The device 10 has as an essential component of a combustion chamber 12, which in the Essentially circular cylindrical formed along an axis 14 is. The combustion chamber 12 is one with respect to FIG. 1 shown above, first end wall 16, one of them starting downwardly extending outer wall 18 and a, 1, bottom, second end wall 20 formed.

The first end wall 16 is arranged centrally Body 22 passes through, which is essentially circular cylindrical is and also extends along the axis 14. The body 22 is concentric with an outer tube 24 and one therein arranged inner tube 26 designed. The outer tube 24 is penetrated by radially outwardly directed nozzles 28, with reference to FIG. 1 at the lower end of the outer tube 24 are located. Otherwise, the outer tube 24 is at this End area closed.

With reference to FIG. 1, the upper end of the outer tube 24 is a further not further illustrated air supply 30 and in Inside the outer tube also not shown in detail Fuel gas supply 32 is provided. Through the air supply 30 and the fuel gas supply 32 becomes air or a first fuel gas fed into the outer tube 24, in which subsequently in Flow direction to the nozzles 28, a mixture 34 of fuel gas and combustion air forms. A first partial stream 36 of this mixture 34 exits a portion of the nozzles 28 into the environment the outer tube 24 and thus into the interior of the combustion chamber 12th out. A second partial stream 38 of the mixture 34 passes through further nozzles 28 ', based on the above-mentioned nozzles 28 of the first partial flow 36 and with reference to FIG. 1 on are arranged at the bottom of the outer tube 24.

The outer tube 24 is substantially of a recirculation space 40 surrounded at the inside of the combustion chamber 12th another combustion chamber 42 connects. Between the recirculation room 40 and the other combustion chamber 42 are on the inside the outer wall 18 flow guide 44 arranged.

With the help of these flow guide 44 and the following explained in more detail introduction of the first partial flow 36th (as well as the second partial flow 38) is within the recirculation space 40 a circulation flow 46 excited and stabilized, starting from the nozzles 28 initially radially directed outwards, subsequently towards the first end wall 16 and directed radially inwardly along this is and finally from the first end wall 16 again reaches the nozzles 28.

At the first end wall 16 is another, not illustrated in detail Fuel gas supply 48 is provided. Through this further Fuel gas supply 48 passes further fuel gas in the circulation flow 46th

From the circulation flow 46 finally occurs in the area from the nozzles 28 'flowing off fuel gas 50 and passes through the further combustion chamber 42 through to an outlet 52, in the end wall 20 as a substantially central Opening is formed. In an embodiment not shown, in which the combustion chamber as an annular combustion chamber is designed, this opening is circular.

During operation of the device 10 is through the outer tube 24, the air supply 30 and the fuel gas supply 32 to the Nozzles 28 and 28 'a mixture 34 of fuel gas and combustion air supplied, in which the ratio of air and fuel gas over the average air / fuel gas ratio of the later combustion is within the combustion chamber 12. That way is a self-ignition of the mixture 34 avoided.

The mixture 34 is the first partial flow 36 and second partial flow 38 introduced substantially radially into the combustion chamber 12. The nozzles 28 are arranged and shaped in this way, that the first partial flow 36 substantially in the Circulation 46 flows and thus within the recirculation space stimulates a recirculation vortex. By Addition of further fuel gas through the further fuel gas supply 48 in a substantially axial direction becomes the recirculation vortex additionally supported and so much energy provided that, in principle, a warm-up of the entire Mixture is ensured on ignition conditions.

At the other fuel gas supply 48 per unit time a admixed such amount of gas that the most homogeneous possible interference takes place in the recirculation vortex and temperature peaks be avoided. The interference takes place at one comparatively low temperature level, so while a Reaction of the fuel gas with the combustion air takes place, this Reaction but only leads to very low NOx emissions. The Fuel gas supply 48 also contributes to the cooling of the first End wall 16 of the combustion chamber 12 at.

Within a stable circulation flow 46 flows per Time unit between about 10% and 20% of the total during a unit of time supplied Brennluft- and fuel gas mass. This total gas mass is preheated in the recirculation vortex. The case achieved combustion or reaction of the mixture 34th takes place with a particularly homogeneous gas mixing and a comparatively low temperature level while avoiding of temperature peaks. On a separate pilot in conventional form or on aerodynamic stabilization measures by swirl generator can therefore at the combustion chamber 12 be waived. Another major advantage of Combustion chamber 12 and the two-stage supply formed thereon of fuel gas in the recirculation space 40 is that on Catalysts can be dispensed with.

The second partial stream 38 of the mixture 34 and optionally further partial flows occurs / occur through the example as Tubes designed nozzles 28 'directly into the outflowing Fuel gas 50 or can at a not shown Recycle full or partial embodiment also. The outflowing fuel gas 50 is comparatively hot, so that the second partial flow 38 is heated in sufficient form and also fully reacted to the exit 52.

Finally, it should be noted that the centrally arranged body 22 and the inner tube 26 formed therein the possibility integration of liquid fuel nozzles so that the device 10 as a whole two-fuel system can be used. With the device 10 can also liquid fuel in a comparatively low-pollution manner and oxidized, which in conventional systems with Catalysts is not possible so far.

Claims (21)

Method for burning fuel in a combustion chamber (12), in which Fuel and combustion air are mixed before entering the combustion chamber (12) while avoiding autoignition, a first part (36) of the mixture (34) is introduced into the combustion chamber (12) in such a way that it circulates in the combustion chamber (12), in the circulation flow (46) of the first part (36) of the mixture (34) further fuel is supplied until a warm-up to ignition conditions would be ensured, and at least a second part (38) of the mixture (34) is introduced into the combustion chamber (12) in such a way that it mixes with a hot fuel gas (50) flowing out of the circulation flow (46), heats up and exits until it leaves the combustion chamber (12) burns. Method according to claim 1,
characterized in that the fuel and the combustion air are mixed before entering the combustion chamber (12) such that the ratio of combustion air to fuel is above the average air / fuel ratio of the combustion in the combustion chamber (12). Method according to claim 1 or 2,
characterized in that the first and / or the at least one second part (36, 38) of the mixture (34) of fuel and combustion air through a centrally in the combustion chamber (12) arranged body (22) is introduced. Method according to claim 3,
characterized in that a fuel gas is supplied as fuel, and in addition by the centrally disposed body (22) liquid fuel is supplied. Method according to one of claims 1 to 4,
characterized in that the circulation flow (46) of the first part (36) of the mixture (34) of fuel and combustion air is formed in a peripheral region (40) of the combustion chamber (12). Method according to one of claims 1 to 5,
characterized in that the combustion chamber (12) is designed substantially cylindrical or annular and the first part (36) of the mixture (34) of fuel and combustion air is introduced substantially radially into the combustion chamber (12). Method according to one of claims 1 to 6,
characterized in that the combustion chamber (12) is substantially cylindrical or annular and the further fuel (48) is introduced substantially axially into the combustion chamber (12). Method according to one of claims 1 to 7,
characterized in that the combustion chamber (12) is designed substantially cylindrical and the at least one second part (38) of the mixture (34) of fuel and combustion air is introduced substantially radially into the combustion chamber (12). Method according to one of claims 1 to 8,
characterized in that the first and at least a second portion (36, 38) of the fuel and combustion air mixture (34) are introduced as a common stream into the combustion chamber (12) which is split within the combustion chamber (12). Method according to one of claims 1 to 9,
characterized in that the first and / or the at least one second part (36, 38) of the mixture (34) of fuel and combustion air through at least one specially adapted nozzle (28, 28 ') in the circulation flow (46) and the combustion chamber ( 12) is initiated. Method according to one of claims 1 to 10,
characterized in that the circulation flow (46) is formed such that circulates per unit time in it between about 5% to 25%, in particular between about 10% and 20%, of the total supplied during a unit of time gas mass. Device (10) for burning fuel in a combustion chamber (12), in particular for carrying out the method according to one of claims 1 to 11, with a mixing device (22) for mixing fuel and combustion air before entering the combustion chamber (12) while avoiding autoignition, a first mixture introduction means for introducing a first part (36) of the mixture (34) into the combustion chamber (12) such that the first part (36) of the mixture (34) circulates in the combustion chamber (12), a fuel introduction means (48) for supplying further fuel into the circulation flow (46) of the first part (36) of the mixture (34) until ignition conditions are present, and at least one second mixture introduction device for introducing at least one second part (38) of the mixture (34) into the combustion chamber (12), such that the at least one second part (38) of the mixture (34) is in contact with one of the circulation flow ( 46) flowing out, hot fuel gas (50) mixes, heats up and burns until its exit from the combustion chamber (12). Device according to claim 12,
characterized in that the first and / or the at least one second mixture introduction device is designed as a centrally arranged in the combustion chamber (12) body (22). Device according to claim 13,
characterized in that the first and / or the at least one second mixture introduction device is designed for introducing gaseous fuel and additionally in the centrally arranged body (22) at least one device for introducing liquid fuel is provided. Device according to one of claims 12 to 14,
characterized in that the first mixture introduction means and the combustion chamber (12) are designed such that the circulation flow (46) of the first part (36) of the mixture (34) of fuel and combustion air in a peripheral region (40) of the combustion chamber ( 12) is created. Device according to one of claims 12 to 15,
characterized in that the combustion chamber (12) is substantially cylindrical or annular in shape, and the first mixture introduction means is configured to substantially radially radially into the combustion chamber the first part (36) of the fuel and combustion air mixture (34). 12). Device according to one of claims 12 to 16,
characterized in that the combustion chamber (12) is substantially cylindrical or annular and the fuel introduction means (48) is designed such that it introduces the further fuel substantially axially into the combustion chamber (12). Device according to one of claims 12 to 17,
characterized in that the combustion chamber (12) is substantially cylindrical or annular in shape and the at least one second mixture introduction means is configured to substantially radially radiate the at least one second portion (38) of the fuel and combustion air mixture (34) into the combustion chamber (12) brings. Device according to one of claims 12 to 18,
characterized in that the first and the at least one second mixture introduction means are adapted to communicate the first and the at least a second part (36, 38) of the mixture (34) of fuel and combustion air as a common stream into the combustion chamber ( 12). Device according to one of claims 12 to 19,
characterized in that the first and / or at least one second mixture-introduction means at least one specially adapted nozzle (28, 28 ') for introducing fuel into the circulation flow (46) and the combustion chamber (12). Device according to one of claims 12 to 20,
characterized in that the combustion chamber (12) and the first and the at least one second mixture introduction means are designed such that in the circulation flow (46) per unit time between about 5% to 25%, in particular between about 10% and 20%, the total circulated during a unit of time gas mass circulates.

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