DE10062253A1 - Gas turbine for aircraft has mesh of heat-resistant material, e.g. ceramic, in its combustion chamber - Google Patents

Abstract

The gas turbine for aircraft has a mesh (2) of heat-resistant material in its combustion chamber (1). This is made from zirconium oxide, alumina or a ceramic.

Description

The invention relates to an aircraft gas turbine with at least least a combustion chamber.

A wide variety of configurations are from the prior art previously known from combustion chambers. The structural design the combustion chambers takes place on the one hand with regard to con structural specifications, on the other hand, to optimize the burning process Mieren and a ge especially with high efficiency rings to cause pollutant emissions.

However, it proves to be a disadvantage in known combustion chambers lig that relatively high in part load and idle Emissions of CO and unburned hydrocarbons exist Furthermore, depending on the combustion chamber configuration and the operating state a not inconsiderable Soot formation. It can also extinguish the flame come when the air-fuel mixture is too lean.

Another disadvantage of known combustion chambers is that they develop resonance vibrations under certain circumstances those who are both acoustically disturbing and especially can lead to flashback especially at high intensity NEN.

The invention is based, an aircraft gas turbine to be designed so that combustion is optimized in the combustion chamber conditions can be realized with low pollutant emissions are.

According to the invention, the object is characterized by the features of Main claim solved. The subclaims show more partial embodiments of the invention.  

According to the invention it is therefore provided that in the combustion chamber a solid framework is arranged.

As is known, combustion chambers of aircraft gas turbines in Strö direction divided into at least three sections. By doing first section takes place the evaporation of the fuel as well a mixture and equalization. On this first ab The actual combustion chamber follows as the second section. A calming section is then provided. When operating the aircraft gas turbine, the fuel is mixed with air premixed and completely pre-evaporated and in the first Ab section of the combustion chamber (mixing chamber) injected. The state of the Technology describes for this purpose, the Brenn chamber upstream components, such as when using Liquid fuels so-called LPP modules.

In order to achieve an optimized combustion under a wide variety of operating conditions, the invention provides that a solid body structure is arranged in the combustion chamber. This results in a number of significant advantages:
According to the invention, the entire combustion chamber is preferably filled with the solid framework. This results in a complete combustion in the combustion chamber in which the solid framework is located. A burnout of <95% can be achieved here.

The solid framework preferably consists of a lot number of struts and ramifications at nodes converge or branch there.  

The solid-state framework can cause a sharp rise in temperature stamped on the gas air mixture entering the combustion chamber become. There is a good ignition of the injek door module (LPP module) introduced, pre-evaporated and with Air premixed fuel. This results in a nied temperature near the adiabatic combustion conditions conditions (while maintaining a high air to fuel ratio).

To optimize the flow through the combustion chamber, it is particularly advantageous if the solid framework is so out will result in no more than 15% of the void volume of the Fills the combustion chamber. In addition, it can be particularly beneficial be when the struts and ramifications of the solid as an aerodynamic streamlined body with optimized Pressure loss are executed. The additional pressure loss dp / p of the installed solid framework is less than 5%.

To cool the wall of the combustion chamber, it can be as prove to be particularly advantageous if the solid framework to Wall of the combustion chamber has a distance. So can Cooling air is passed freely along the combustion chamber wall become.

The solid-state framework according to the invention acts in several points of view. On the one hand it keeps the flame in the combustion chamber, on the other hand it transports heat against the direction of flow through its heat radiation and thus warms the incoming gas. It is therefore particularly advantageous if the physical surface structure of the solid framework is designed so that it largely corresponds to that of a dark, gray emitter (emissivity <0.8). Furthermore, it is advantageous if the struts and ramifications of the solid body structure are designed such that the largest possible radiation-effective surface is achieved. For example, values of more than 100 m ² on the surface of the solid framework per m ^{3 of} empty combustion chamber volume can be realized.

The solid-state framework according to the invention thus acts in particular as a spotlight and holds the flames. It therefore does not form a Ka and does not only serve to influence the Gas flow.

The advantage according to the invention is that the emissions unburned hydrocarbons, CO and soot significantly reduced become. Furthermore, the lean flame extinguishing limit becomes clear Lich postponed. Another advantageous effect is in acoustic damping, which avoids resonance vibrations or be mitigated.

Due to the flame stabilization achieved by means of the solid framework lity can be associated with low-NOx combustion concepts (e.g. LPP modules) who do not have pilot burners the. LPP modules result in an almost complete pre-evaporation liquid fuel (kerosene).

Since the aircraft gas turbine designed according to the invention is characterized by is characterized by a very high burnout (<95%), it is possible shorten the entire length of the combustion chamber significantly, because shorter residence times of the gases in the combustion chamber are necessary to achieve the fuel burnout. The shorter residence times of the gases also minimize the thermal NOx emissions.

It is also advantageous that the temperature distribution at the combustion chamber outlet is very uniform and has only a very slight variance from the mean. In a particularly favorable embodiment of the invention it is provided that the solid body structure consists of a highly heat-resistant material. This can be, for example, a highly heat-resistant ceramic that is not prone to oxidation, preferably, for example, zirconium oxide ZrO ₂ or aluminum oxide Al ₂ O ₃ . In an alternative, advantageous embodiment, it can also be provided that the solid structure is designed in the form of a ceramic-fiber composite structure or a ceramic jacket-metal support structure. Overall, the struts and branches of the solid framework are designed so that they can withstand the adiabatic flame temperature of the incoming fuel-air mixture (temperatures <1000 ° C).

In the following the invention is based on two embodiments games described in connection with the drawing. there shows:

Fig. 1 is a schematic, greatly simplified representation of a stepped combustion chamber using the solid framework according to the invention, and

Fig. 2 shows a further embodiment of a combustion chamber according to the invention.

In the figures, the same components with the same reference number referred to distant.

Figs. 1 and 2 each show a schematic Darge set, greatly simplified combustion chamber 1 with a merwandung Brennkam. 6 The shape and design of the combustion chambers corresponds essentially to the prior art, so that the description of further details can be omitted.

In the two embodiments, an injector module (LPP module) 4 is provided, with the aid of which the fuel is injected and gasified.

A mixing chamber 3 connects to the LPP module 4 . According to the invention, a solid-state framework 2 is arranged in the flow direction behind the mixing chamber 3 , which consists of a large number of struts and / or branches which converge at branch points and / or branch there. The individual ramifications and struts have not been shown in detail for the purpose of simplified representation.

The solid framework 2 is at a distance from the wall 6 in order to allow the passage of cooling air for cooling the wall.

Subsequent to the solid framework 2 , a calming section 5 is formed in the combustion chamber.

The solid framework 2 fills, as shown in Figs. 1 and 2 Darge, essentially the entire combustion chamber of the Brennkam mer. With regard to the dimensioning, reference is made to the preceding explanations.

LIST OF REFERENCE NUMBERS

1

combustion chamber

2

Solid structure

3

mixing chamber

4

Injector module / LPP module

5

calming section

6

wall

Claims (11)

1. aircraft gas turbine with at least one combustion chamber ( 1 ), characterized in that a solid body is arranged in the combustion chamber ( 2 ). 2. Aircraft gas turbine according to claim 1, characterized in that the solid body structure ( 2 ) consists of a plurality of Ver struts and ramifications, which converge at nodes or branch. 3. aircraft gas turbine according to claim 1 or 2, characterized in that the solid frame ( 2 ) consists of a highly heat-resistant material. 4. Aircraft gas turbine according to one of claims 1 to 3, characterized in that the solid framework ( 2 ) is made of a heat-resistant ceramic that does not tend to oxidation. 5. Aircraft gas turbine according to claim 4, characterized in that the solid body structure ( 2 ) consists of ZrO ₂ . 6. Aircraft gas turbine according to claim 4, characterized in that the solid body structure ( 2 ) consists of Al ₂ O ₃ . 7. Aircraft gas turbine according to one of claims 3 to 6, characterized in that the solid structure ( 2 ) is made in the form of a ceramic-fiber composite structure. 8. Aircraft gas turbine according to one of claims 3 to 6, characterized in that the solid frame ( 2 ) is made in the form of a ceramic jacket-metal support structure. 9. Aircraft gas turbine according to one of claims 1 to 8, characterized characterized that the struts and / or branches lungs in the form of aerodynamic streamlined bodies forms are. 10. Aircraft gas turbine according to one of claims 1 to 9, characterized in that the physical surface texture of the solid structure ( 2 ) corresponds to that of a dark, gray beam. 11. Aircraft gas turbine according to one of claims 1 to 10, characterized characterized that the solid framework is the same or we fills less than 15% of the empty volume of the combustion chamber.