EP2023041A1 - Premix burner and method for operating a premix burner - Google Patents

Abstract

The method involves injecting an air mass flow (5) and fuel (6) e.g. synthetic gas, into a premixing zone (2) of a premixing burner (1) for forming a potential hot gas backflow area. A fluid (15) e.g. inert gas, which does not contain fuel, is injected downstream towards a fuel injection into the premixing zone. The fluid is injected into the premixing zone along the surface area of the premising zone in a main flow direction (9). The fuel is injected into the premixing zone perpendicular to the main flow direction of the air mass flow. An independent claim is also included for a premixing burner comprising a premixing zone.

Description

The present invention relates to a premix burner, in particular a synthesis gas premix burner, and a method of operating a premix burner.

Premix burners typically include a premix zone in which air and fuel are mixed before passing the mixture into a combustion chamber. There, the mixture burns, producing a hot gas under elevated pressure. This hot gas is forwarded to the turbine. In connection with the operation of premix burners, it is particularly important to keep the nitrogen oxide emissions low and to avoid a flashback.

Synthesis gas premix burners are characterized by the fact that synthesis gases are used as fuel in them. Compared with the traditional turbine fuels natural gas and petroleum, which consist essentially of hydrocarbon compounds, the combustible components of the synthesis gas are essentially carbon monoxide and hydrogen. Depending on the gasification process and the overall plant concept, the calorific value of the synthesis gas is about 5 to 10 times smaller than that of natural gas.

In addition to the stoichiometric combustion temperature of the synthesis gas, the quality of the mixture between synthesis gas and air at the flame front is an important influencing factor for avoiding temperature peaks and thus for minimizing the formation of thermal nitrogen oxides.

The main constituents of the synthesis gas are not only carbon monoxide and hydrogen but also inert fractions. The inert fractions are nitrogen and / or water vapor and optionally carbon dioxide. Due to the low Heat value must therefore be introduced into the combustion chamber high volume flows of fuel gas. As a result, significantly larger injection cross sections are required for the combustion of low-calorie fuels, such as synthesis gases, than with conventional high-calorie combustion gases.

The air mass flow introduced into the combustion chamber is typically twisted by means of an air swirl generator. In this twisted air mass flow, the fuel is injected via one or more juxtaposed or successively arranged circular rows of holes.

In order to ensure a sufficient mixing between fuel and air, a sufficient penetration depth of the individual fuel jets in the air mass flow is necessary. In comparison to high-calorie combustion gases such as natural gas, correspondingly larger, free injection cross sections are required. This has the consequence that the fuel jets disturb the air flow sensitive, which ultimately leads to a local separation of the air flow in the wake region of the fuel jets. The forming Rückströmgebiete within the burner are undesirable and especially in the combustion of highly reactive synthesis gas necessarily to avoid. In extreme cases, these local Rückströmgebiete lead within the mixing zone of the burner to a flashback in the premixing zone and thus to a burner damage.

The risk of flashback can be largely avoided by the combustion of highly reactive synthesis gases in the diffusion mode. For the realization of low nitrogen oxide emissions, however, an optionally strong dilution with inert gases, preferably with steam, is necessary. In the case of a premix combustion, the formation of follow-up areas or Heißgasrückströmgebieten within the burner by appropriate shaping of Eindüsbohrungen reduced, but not avoided in principle.

In EP 1 614 963 A1 In order to reduce nitrogen oxide emissions and to prevent flashbacks in the combustion of low calorific fuels for the operation of a gas turbine, a method is proposed in which a low calorific fuel is premixed with air in stages.

In EP 1 614 967 A1 Furthermore, a method for the combustion of a low calorific fuel for the operation of a gas turbine is proposed, in which the low calorie fuel is premixed with air to a low calorific fuel-air mixture in a premix and a conversion of the low calorific fuel-air mixture is avoided.

Specially designed to prevent flashbacks in EP 1 507 120 A1 proposed a gas turbine with an annular combustion chamber, in which a swirl grating is arranged in a combustion air inlet region around the entire circumference of the annular combustion chamber, whereby a higher flow rate of the incoming combustion air is achieved compared to individual air inlet regions, each with a swirl grating. This results in a higher safety against flashbacks and a lower tendency to form combustion oscillations.

In order to ensure a safe premixing operation, flow separation or a backflow region within the premixing zone of the burner must be avoided at all costs. But at least potential return flow areas are to be designed in such a way that no damage to the burner takes place. As a rule, the backflow areas occur in near-wall zones in the wake of the fuel gas jets.

With regard to the reduction of nitrogen oxides, in particular the addition of inert mass streams as diluent in the Air mass flow or the fuel mass flow (quenching) usual. The use of lean premix technology enables the reduction in the amount of diluent used, increasing plant economics. Due to the then missing inertization but then there is a highly reactive fuel.

The object of the present invention is to provide an advantageous method for operating a premix burner, in which the formation of hot gas backflow regions is avoided. Another object of the present invention is to provide an advantageous premix burner.

These objects are achieved by a method for operating a premix burner according to claim 1 and a premix burner according to claim 10. The dependent claims contain further, advantageous embodiments of the invention.

The method of the invention relates to a premix burner comprising a premix zone. In the combustion chamber, an air mass flow and fuel is injected, whereby a potential Heißgasrückströmgebiet can form. The inventive method is characterized in that a non-fuel-containing fluid is injected downstream of the fuel injection in the premixing zone.

Due to the local injection of, for example, cold air in the wake or Rückströmgebiete the training selbiger is largely prevented within the Vormischzone of the burner. At least the fuel in these areas is diluted and cooled to the extent that no reaction or ignition of the fuel-air mixture can occur within the premixing zone of the burner. This allows a safe premix operation of the burner.

In particular, the fluid can be injected into the premixing zone along the surface of the premixing zone in the main flow direction which is located in the potential hot gas backflow region. The injection of a fluid along the component surface in the main flow direction prevents the actual formation of the Heißgasrückströmgebietes and / or diluted and cools the local fuel-air mixture from such that no ignition conditions prevail.

The fuel can in particular be injected perpendicular to the main flow direction of the air mass flow in the premixing zone, which is advantageous in terms of a thorough mixing of air and fuel. In principle, it is possible to inject the fuel at the cone side and / or at the hub side into the premixing zone. Furthermore, the fuel can be injected via at least one swirl blade into the premixing zone. The fuel may in particular also be a synthesis gas.

The fluid injected into the premixing zone along the surface located in the potential hot gas return flow region can be, for example, air or an inert gas. Inert gases are gases that are very slow to react, meaning they participate in only a few chemical reactions. In particular, carbon dioxide, water vapor, nitrogen, but also all noble gases can be used as the inert gas. The use of an inert gas is particularly suitable if ignition conditions for highly flammable fuels should be avoided.

When using air as a fluid injected into the premixing zone, it is advantageous to use air of the air mass flow which is in any case supplied to the premixing zone. For example, a proportion of 10% of the total air supplied to the premixing zone can be branched off and injected into it along the surface of the premixing zone located in the potential hot gas backflow region. The proportion of along The surface of the premixing zone located in the potential hot gas return flow area can be selected as desired. The height of the preferably used portion of the air depends on the geometry of the premixing zone, on the velocity of the air mass flow and the velocity of the injected fuel.

The premix burner of the present invention includes a premix zone, an air swirler with an air supply, and one or more fuel nozzles. In this case, the fuel can be injected through the fuel nozzles into a mass air flow that is twisted by the air swirler in the premixing zone, whereby a potential hot gas backflow region can form. The premix burner according to the invention is characterized in that the premix zone surface in the potential Heißgasrückströmgebiet has at least one opening through which a fluid can be injected into the premixing zone. In particular, there may be openings arranged so that the fluid can be injected in the main flow direction of the burner along the surface of the premixing zone.

The local injection of a fluid into the potential Heißgasrückströmgebiet the formation of Heißgasrückströmgebietes is largely prevented within the Vormischzone of the burner. At least, however, the hot gas in the Heißgasrückströmgebiet so far diluted and cooled that no reaction in the form of an inflammation of the air-gas mixture can occur within the Vormischzone of the burner. This prevents flashbacks and reduces the formation of nitrogen oxides, thus enabling safe premixing operation of the burner.

Preferably, the premixing zone surface has a plurality of openings in the hot gas backflow region. The opening or the openings can advantageously be connected via a fluid channel with the leading to the air swirler air supply so be that through the opening part of the air can be injected as fluid into the combustion chamber.

The fuel nozzles may be located on the cone side and / or on the hub side of the premix zone. Advantageously, the fuel nozzles are arranged in one or more consecutive rows downstream of the air swirler. This allows a graduated fuel injection. Furthermore, the fuel nozzles and / or the openings may be located in the air swirler, preferably in at least one swirl vane.

The individual fuel nozzles can be designed, for example, as round bores. Another possibility is to design the fuel nozzles so that the fuel can be injected perpendicular to the main flow direction of the air mass flow into the combustion chamber, which promotes the mixing. Of course, the fuel can be injected at any other angle to the air mass flow. The fuel used may in particular be a synthesis gas.

• Fig. 1 zeigt schematisch einen Schnitt durch einen Teil eines Vormischbrenners.
• Fig. 2 zeigt schematisch die Strömungsverhältnisse im Inneren des in Figur 1 gezeigten Vormischbrenners.
• Fig. 3 zeigt schematisch einen Schnitt durch einen Teil eines erfindungsgemäßen Vormischbrenners.
• Fig. 4 zeigt schematisch die Strömungsverhältnisse im Inneren des in Figur 3 gezeigten Vormischbrenners.
• Fig. 5 zeigt schematisch einen Schnitt durch eine Drallschaufel.

Further features, properties and advantages of the present invention will be described below by means of an embodiment with reference to the accompanying figures.

• Fig. 1 schematically shows a section through a part of a premix burner.
• Fig. 2 schematically shows the flow conditions in the interior of FIG. 1 shown premix burner.
• Fig. 3 schematically shows a section through a part of a premix burner according to the invention.
• Fig. 4 schematically shows the flow conditions in the interior of FIG. 3 shown premix burner.
• Fig. 5 schematically shows a section through a swirl blade.

The invention will be described below with reference to FIGS FIGS. 1 to 5 described in more detail. The FIG. 1 1 schematically shows a section through a part of a conventional premix burner 1. The premix burner 1 comprises inter alia a housing 7, a premix zone 2, an air swirler 10 and one or more fuel nozzles 11. The premix zone 2 is arranged radially symmetrically about the center axis 12. The outer side of the premixing zone 2 seen from the center axis 12 is referred to below as the cone side 3. The side of the premixing zone 2 facing the center axis 12 is referred to below as the hub side 4.

Via an air supply 16, an air mass flow 5 reaches the air swirler 10. The air swirler 10 swirls the air mass flow 5 and forwards it into the premixing zone 2. From there, the air mass flow in the main flow direction 9 to the combustion chamber (not shown) forwarded.

One or more fuel nozzles 11 are located on the hub side 4 of the premixing zone 2. In the present example, fuel 6 directs fuel 6 perpendicular to the main flow direction 9 of the air mass flow 5 into the premixing zone 2. Downstream of the fuel nozzle 11 in the main flow direction 9 now forms a Heißgasrückströmgebiet 8 from. Instead of a vertical injection to the main flow direction 9 of the air mass flow 5, the fuel 6 can be injected at any other angle to the main flow direction 9.

The flow direction of the injected fuel is indicated by arrows 6, the flow direction of the supplied air mass flow is indicated by arrows 5. The Main flow direction in the interior of the premixing zone 2 is marked by arrows 9.

In FIG. 2 the flow conditions in the interior of the premixing zone 2 are sketched schematically. You can see in FIG. 2 a plan view of the fuel nozzles 11 from the interior of the premixing zone 2 from. The main flow direction of the air mass flow flowing past the fuel nozzles is indicated by arrows 9. Downstream of the fuel nozzles 11 in the main flow direction 9 now form Heißgasrückströmgebiete 8 from. The flow direction of the flowing back hot gas is indicated by arrows 13.

The FIG. 3 schematically shows a section through a part of a premix burner according to the invention 1. The basic structure and the basic operation of the in FIG. 3 The premix burner 1 shown substantially corresponds to that or of the in connection with the in FIG. 1 shown premix burner.

In addition to that related to FIG. 1 The premix burner according to the invention comprises one or more fluid inlet openings 14 which are located downstream of the fuel nozzle or nozzles 11 in the main flow direction 9. The fluid inlet openings 14 open into the premixing zone 2. In the present exemplary embodiment, through these fluid inlet openings 14, a fluid, for example air or an inert gas, can be injected into the premixing zone 2 in the main flow direction 9. The direction of flow of the injected fluid is indicated by arrows 15. It runs within the premixing zone 2 substantially parallel to the main flow direction 9. The injected fluid prevents the formation of a Heißgasrückströmgebietes, as in the associated with FIG. 1 described premix burner occurs.

In FIG. 4 are the flow conditions inside the in FIG. 3 shown schematically schematically. you looks in FIG. 4 a plan view of the fuel nozzles 11 and the fluid inlet openings 14 seen from the premixing zone 2 from. The main flow direction of the air flowing from the swirl generator 10 in the direction of the fuel nozzles 11 and the fluid inlet openings 14 is indicated by arrows 9. The direction of flow of the fluid injected through the fluid inlet openings 14 is indicated by arrows 15. By the inflowing fluid, the hot gas 13 is entrained in the main flow direction 9. A backflow of the hot gas 13 against the main flow direction 9 is effectively prevented in this way.

In the present exemplary embodiment, the fluid injected via the fluid inlet openings 14 is air which is connected to the air mass flow 5 via a fluid channel and branched off from it. It has been found favorable with regard to avoiding the hot gas backflow to supply about 5% to 20%, preferably 10%, of the total air supplied to the premix zone 2 via the fluid inlet openings 14 of the premix zone 2. Instead of the air, an inert gas, for example carbon dioxide, water vapor or nitrogen, can alternatively be injected into the premixing zone 2 via the fluid inlet openings 14. But also the injection of a noble gas is possible in principle.

The fuel can optionally be injected perpendicular to the main flow direction 9 of the air mass flow 5 in the premixing zone 2, as in connection with FIG. 1 and FIG. 3 described or the fuel can be injected at any angle to the main flow direction 9 of the air mass flow in the premixing zone 2. In principle, the fuel nozzles 11 can be located both on the cone side 3 and on the hub side 4 of the premixing zone 2 or in the swirl blades 17. In the event that the fuel nozzles 11 are located on the cone side 3 of the premixing zone 2, it is advantageous to place the fluid inlet openings 14 correspondingly on the cone side 3 as well. The fluid inlet ports 14 should turn in the main flow direction 9 downstream of the fuel nozzles and allow injection of the fluid in the main flow direction 9.

The fuel nozzles 11 may be disposed in one or more rows one behind the other downstream of the air swirler 10. They can advantageously be designed as round holes. The fuel injected by it may in particular also be a synthesis gas.

In the following, a further embodiment variant of the invention will be described in which the fuel 6 and the non-fuel-containing fluid 15 are injected via swirl vanes 17 into the premixing zone. In FIG. 5 schematically a section through a swirl blade 17 is shown. The swirl blade 17 has in its interior a fuel flow channel 18 and a downstream of the main flow direction 9 fluid flow channel 19.

The fuel 6 is injected via the fuel flow channel 18 through fuel nozzles 11 from the swirl blade 17 into the premixing zone 2. The fluid 15, which is preferably an inert gas, is injected via the fluid flow channel 19 through fluid inlet openings 20, 21, 22 into the premixing zone 2. In this case, the fluid inlet openings 20, 21, 22 are located downstream of the fuel nozzles 11 in the main flow direction 9.

In the present embodiment variant, part of the fluid 15 is injected into the premixing zone 2 through fluid inlet openings 20, which are arranged downstream of the fuel nozzles 11, substantially in the direction opposite to the main flow direction 9. By means of fluid inlet openings 21 arranged further downstream of the fluid inlet openings 20, part of the fluid 15 is injected into the premixing zone 2 almost perpendicular to the main flow direction 9. Downstream of the fluid inlet openings 21 further fluid inlet openings 22 are arranged through which a portion of the fluid 15 is injected into the premixing zone 2 substantially in the main flow direction 9.

The described arrangement of the fluid inlet openings 20, 21, 22, the formation of a Heißgasrückströmgebietes downstream of the fuel nozzles 11 is avoided, thus enabling a safe Vormischbetrieb the burner.

Claims (18)

Method for operating a premix burner (1) which comprises a premixing zone (2) into which an air mass flow (5) and fuel (6) are injected, whereby a potential hot gas backflow region (8) can form,
characterized in that
a non-fuel-containing fluid (15) is injected downstream of the fuel injection into the premixing zone (2). Method according to claim 1,
characterized in that
Fluid (15) is injected along the in the potential Heißgasrückströmgebiet (8) located surface of the premixing zone (2) in the main flow direction (9) in the premixing zone (2). Method according to claim 1 or 2,
characterized in that
Fuel (6) perpendicular to the main flow direction (9) of the air mass flow (5) is injected into the premixing zone (2). Method according to one of claims 1 to 3,
characterized in that
the premixing zone (2) comprises a cone side (3) and a hub side (4) and fuel (6) is injected at the cone side (3) and / or the hub side (4) into the premixing zone (2). Method according to one of claims 1 to 4,
characterized in that
Fuel (6) via at least one swirl blade (17) is injected into the premixing zone (2). Method according to one of claims 1 to 5,
characterized in that
it is the fuel (6) is a synthesis gas. Method according to one of claims 1 to 6,
characterized in that
the fluid (15) is air or an inert gas. Method according to claim 7,
characterized in that
the inert gas is a noble gas, carbon dioxide, water vapor or nitrogen. Method according to claim 7,
characterized in that
the fluid (15) is air and a proportion of 10 percent of the total air supplied to the premix zone (2) is injected along the surface of the premix zone located in the hot gas backflow region (8). Premix burner (1) comprising a premixing zone (2), an air swirl generator (10) with an air supply (16) and at least one fuel nozzle (11), wherein fuel (6) through the fuel nozzle (11) into one of the air swirl generator (10 ) can be injected in the premixing zone (2) twisted air mass flow, wherein a potential Heißgasrückströmgebiet (8) is formed,
characterized in that
the burner surface in the potential Heißgasrückströmgebiet (8) has at least one opening (14) through which a fluid (15) can be injected into the premixing zone (2). Premix burner (1) according to claim 10,
characterized in that
the opening (14) is connected via a fluid channel to the air supply (16) leading to the air swirler (10) such that through the opening (14) part of the air can be injected as fluid (15) into the premixing zone (2). Premix burner (1) according to claim 10 or 11,
characterized in that
the premixing zone (2) comprises a cone side (3) and a hub side (4) and fuel nozzles (11) on the cone side (3) and / or the hub side (4) of the premixing zone (2). Premix burner (1) according to one of claims 10 to 12,
characterized in that
the fuel nozzles (11) are arranged in one or more consecutive rows downstream of the air swirler (10). Premix burner (1) according to one of claims 10 to 13,
characterized in that
There are fuel nozzles (11) and / or the openings (14) in the air swirler (10). Premix burner (1) according to one of claims 10 to 14,
characterized in that
the fuel nozzles (11) are designed as round bores. Premix burner (1) according to one of claims 10 to 15,
characterized in that
the fuel nozzles (11) are designed so that the fuel (6) can be injected perpendicular to the main flow direction (9) of the air mass flow in the premixing zone (2). Premix burner (1) according to one of claims 10 to 16,
characterized in that
it is the fuel (6) is a synthesis gas. Premix burner (1) according to one of claims 10 to 17,
characterized in that
There are openings through which the fluid (15) in the main flow direction of the air mass flow in the premixing zone (2) along the surface of the premixing zone (2) can be injected into the premixing zone (2).

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