EP1199520A1 - Heat shield element for lining a combustion chamber wall, combustion chamber and gas turbine - Google Patents

Abstract

Thermal shield comprises a hot side subjected to a hot medium and a wall side lying opposite the hot side; a hot side region bordering the hot side; and a wall side region bordering the wall side. The grain size in the wall side region is less than in the hot side region. Preferred Features: The grain size in the wall side region is 0.4-0.9, especially 0.6-0.8 less than in the hot side region. The grain size in the hot side region is 1.5-3.5, especially more than 2 mm. The shield is made from aluminum oxide and aluminum silicate, in which the concentration of the aluminum oxide is greater in the wall side region than in the hot side region.

Description

The invention relates to a heat shield brick, in particular for lining a combustion chamber wall, with a hot one Medium hot side and one opposite the hot side Wall side. The heat shield stone instructs you the hot side area adjacent to the hot side and one the wall side area adjacent to the wall side. The invention further relates to a combustion chamber with an inner one Combustion chamber lining and a gas turbine.

In order to make a component exposed to extremely high temperatures, for example a heat shield element, for example a heat shield brick or a gas turbine blade, heat-resistant, it is known, for example, from US Pat To coat ZrO ₂ . The ceramic thermal insulation layer is connected via a metallic adhesive layer made of an alloy of the MCrAlY type. Since the ceramic thermal barrier coating is generally a good oxygen ion conductor, the adhesive layer is oxidized during the operational use of the component, which can lead to detachment of the thermal barrier coating from the metallic base body. This limits the period of use of such a component. This is particularly the case with frequent temperature changes which occur when starting and stopping a gas turbine.

In the article "Ceramic Gradient Materials for Components in Internal Combustion Engines" by W. Henning et al. in metal, 46th volume, issue 5, May 1992, pages 436 to 439, a fiber ceramic body with density gradients is specified to improve the resistance to temperature changes of piston crowns. This fiber ceramic body is made up of four layers of different layer thickness with different ceramic content. The difference in the ceramic part is that the ratio of fibers (Al ₂ O ₃ short fibers) to ceramic particles made of Al ₂ TiO _{5 of} the four layers differs significantly. As a result, the porosity of the four layers is clearly different from one another. The high porosity of the layers between 40% and 79% is used to press-cast molten metal into the cavities of the fiber ceramic body to produce a defect-free bond. As a result, a piston crown can be produced which has a strongly abruptly changing gradient of metal and ceramic. Due to the low thermal conductivity of the ceramic components, a thermal barrier is formed and the piston is thus insulated. In addition, the ceramic fiber reinforces the piston mechanically and thus improves the thermal shock resistance of the piston.

In the article "Projected Research on High Efficiency Energy Conversion Materials ", by M. Niino, M. Koizumi in FGM 94, Proceedings of the 3rd International Symposium on Functional Gradient Materials, ed. B. Ilschner, N. Cherradi, pp. 601-605, 1994, composite materials are related to the development of materials for a space glider specified as Functional Gradient Material (FGM). essential FGM is characterized by a continuous composition and / or microstructure gradient leading to a continuous Gradients of the relevant functions, e.g. strength, Thermal conductivity, ductility and the like should lead, by avoiding abrupt changes in properties the resilience and efficiency of the material increased shall be. FGM are said to have positive properties of layer and piece composites in one material.

From WO 98/53940 is a metal-ceramic gradient material, especially for a heat shield or a gas turbine blade, known. The metal-ceramic gradient material has a metallic base material, a ceramic and one Additive for high-temperature oxidation protection on. The concentration of the metallic base material increases from a metal-rich zone to a ceramic-rich one Zone off, the concentration of the additive having a concentration gradient having. In WO 98/53940 is further a method for producing a metal-ceramic gradient material and a product made therefrom, for example a gas turbine blade or a heat protection element a gas turbine.

The object of the invention is to provide an improved heat shield brick, especially for lining a combustion chamber wall, specify. The heat shield stone is intended especially with regard to the different requirements on the one hot medium, e.g. a hot gas, removable hot side and the wall side opposite the hot side his. Another object of the invention is a combustion chamber with an internal combustion chamber lining as well as a Specify gas turbine.

The first-mentioned object is achieved according to the invention by a heat shield brick, especially for lining one Combustion chamber wall, with one that can be exposed to a hot medium Hot side and a wall side opposite the hot side, and with a hot side area adjacent to the hot side as well as a wall side area adjacent to the wall side, where on average the grain size in the wall side area is smaller than in the hot side area.

The invention is based on the observation that the requirements on heat shield stones on the hot side and the Hot side opposite wall side are different. When operating a heat shield stone, the heat shield stones are for example in combustion chambers of stationary gas turbines used and serve the thermal insulation of the usually metallic combustion chamber wall. A heat shield stone is adjacent with its wall side over a Support structure attached to the combustion chamber wall. The hot side is a hot medium in operation, for example the hot one Combustion gas, exposed. Because of the conditions of use are therefore essential on the hot side of the heat shield stones different requirements than a lot colder wall side. That is in a gas turbine combustion chamber Hot side of the heat shield stones of a high stress through fast flowing, corrosive, hot gases with typical Exposed to temperatures of around 1500 ° C. You also have to due to loading and unloading processes of the gas turbine frequently abrupt temperature changes of up to 1000 ° C can be endured. The lifetimes sought under these conditions the stones are around 50,000 operating hours.

With the invention, a new path is taken, some of which competing requirements, such as high strength on the wall side and, in contrast, enduring high Thermal stresses, temperature and temperature change resistance on the hot side, with the proposed heat shield brick better connect with each other. The relevant critical areas, namely the area adjacent to the hot side Hot side area and the one adjacent to the wall side Wall side area of the heat shield brick in terms of their Structure specifically adapted to the respective requirements. Here the grain size distribution in the hot side area and in the wall side area to the respective area thermomechanical load adjusted. As a selected one The grain size in the wall side area is the structural parameter and set in the hot side area, with on average the Grain size in the wall side area is smaller than in the hot side area. The mean is the mean of the grain size the grain size diameter distribution in a particular area Roger that. With one adapted to the requirements Grain size structuring of the respective areas is one regarding adapted to the load and compared to conventional ones Heat protection elements improved heat shield stone realized. In particular, the requirements of a great thermal shock resistance in the hot side area as well a great strength in the wall side area with each other a heat shield stone can be realized.

The heat shield brick can advantageously consist of one consist of uniform material, for example from a refractory material, just setting the different Grain sizes in the wall side area and in the hot side area he follows. Already through the structural adjustment of the heat shield stone the desired result is achieved. But it is also quite possible to have a stone with different ones chemical compositions, for example select a mixture of two or more substances and the structural adjustment in terms of grain size in the wall side area and in the hot side area according to the Make invention in a corresponding manner. The invention is characterized by a high flexibility, because the relevant parameters, namely the grain size distribution or the arithmetic mean of this, a structural parameter is a priori independent of the chemical composition influenceable and thus with regard to the above Requirements is adjustable.

The grain size in the wall side region is preferably approximately a factor of 0.4 to 0.9, in particular a factor of 0.6 to 0.8, smaller than in the hot side area. Through these scaling factors is the grain size in the hot side area and adjustable relative to each other in the wall side area, so that one of absolute dimensions of the heat shield stone and the relevant load areas (hot side area, wall side area), is largely independent. advantageously, are heat shield stones of different geometries, Material thickness or composition, with load range specific Grain size adjustment can be implemented.

The average grain size in the hot side area is preferably between about 1.5 mm and 3.5 mm. In particular, The grain size in the hot side area is larger than about 2 mm.

The average grain size in the wall side area is preferably between about 0.6 mm and 1.4 mm. In particular, The grain size in the wall side area is smaller than about 1.2 mm.

With the dimensioning of the grain size according to the above Limits are in particular heat shield stones with dimensions, as is usually the case when using a heat shield brick the combustion chamber of a gas turbine are important, appropriate to the load be specified. In the specific case, of course, is empirical and / or the respective thermomechanical Load in the wall side area and in the hot side area determine, and a load-compatible grain size in the areas to be provided precisely.

In a particularly preferred embodiment, along a Direction from the hot side to the wall side with layers decreasing grain size provided.

An average grain size is found in the layers set so that from the hot side area to the wall side area the average grain size decreases in layers. In each layer is preferably a respective grain size set. This layered gradation of the set Grain sizes in the layers are advantageously carried out gradually, so that impermissibly large changes (jumps) largely avoided and a in the material properties Heat shield stone with adapted to the requirements Properties is achievable. The relevant material properties, e.g. Strength, thermal conductivity, ductility and the like, can be avoided by avoiding abrupt Property changes to increase resilience and efficiency of the heat shield stone. advantageously, can the wall side area and / or the Hot side area a respective layer with corresponding Have grain size adjustment.

The number of layers is preferably about 5 to 30, especially about 10 to 20.

The exact choice of the number of layers depends on the respective one Case of stress and the required gradual adjustment the grain size from the hot side area to the wall side area from. Technically, for example Manufacture of such a heat shield brick with a reference the structure gradients set in this way done that a powder with a base material for the Heat shield stone, for example a ceramic or another Refractory material, one on top of the other to form a bed is poured in layers, and that the filling afterwards correspond to pressed and to the one structural gradient having heat shield stone is sintered, wherein on average the grain size in the wall side area is smaller than in the hot side area and according to the number of layers the grain size is gradually adjusted.

Preferably changes along a direction from the hot side on the wall side the grain size is essentially continuous.

A continuous change in grain size is special advantageous because practically any sudden changes in the relevant material properties at the transition avoided from the wall side area to the hot side area become. By a correspondingly high number of layers a quasi-continuous adjustment can be achieved.

In terms of manufacturing technology, such a continuous adjustment is required accordingly more complex. A continuous or quasi-continuous transition of the grain size distribution (Mean value of the grain size diameter distribution) can for example in a linear function. Generally can also use higher-order polynomials or others continuous or continuously differentiable functions make this transition to reach. The choice depends on the type of load and the course of the load from the hot side to the wall side of the heat shield brick to meet appropriately and accordingly Apply functions for adjusting the transition.

In a particularly preferred embodiment, the heat shield brick from at least two fabrics, with a first Fabric and composed of a different second fabric.

This configuration also advantageously means heat shield stones, which consist of at least a two-substance mixture, according to the concept of the invention with an area-specific Grain size adjustment can be configured. In addition to two-substance mixtures are also heat shield stones that consist of more than two chemical compounds are composed with regard to their Grain size distribution can be structured.

The concentration of the first substance in the Wall side area larger than in the hot side area.

This will take advantage of structural adjustment the grain size in the hot side area and in the wall side area advantageously in terms of chemical adjustment the concentration of the first substance in the wall side area and combined in the hot side area. To the structural There is a chemical gradation in two-substance mixtures Gradation, which like the structural also gradually with one Layer system or essentially continuous from that Hot side area is feasible in the wall side area.

By grading the grain size and chemical composition can make abrupt changes in material properties can be avoided in a particularly advantageous manner. The adaptation of the heat shield brick to the thermomechanical This further improves requirements. Due to the grain size and concentration adjustment is multi-dimensional Parameter space for a load area specific design of a heat shield stone reached.

The first fabric with the higher concentration in the wall side area than in the hot side area, advantageously has Properties based on the strength in the wall side area increase the strength in the hot side area, because due to the requirements, for example, when using the Heat shield stone in the combustion chamber of a gas turbine, the Wall side area that requires greater strength. In contrast, is the strength requirement in the hot side area of of minor importance compared to thermal shock resistance in the hot side area. Therefore, the concentration of the first fabric in the hot side area compared to the cold side area preferably set lower. The adjustment of the Concentration, d. H. the concentration gradient of the first The substance and / or the second substance is advantageously carried out gradually in corresponding layers or is in adjusted continuously.

The first substance is preferably an oxide and the second Substance is a silicate, especially a silicate ceramic.

The first substance is preferably aluminum oxide Al ₂ O ₃ and the second substance aluminum silicate 3Al ₂ O ₃ • 2SiO ₂ .

Heat shield stones of a quality which contain aluminum silicate 3Al ₂ O ₃ .2SiO ₂ and aluminum oxide Al ₂ O ₃ have proven to be particularly well suited for use under the conditions described above. The aluminum oxide can be introduced as corundum (roughly crystalline). Aluminum oxide forms very hard, colorless crystals and has a high melting point at 2050 ° C. It is therefore particularly suitable for high-temperature applications as part of a heat shield brick. Aluminum silicate 3Al ₂ O ₃ • 2SiO ₂ , also known as mullite, is formed, for example, by burning (heating) shaped, moist clay, possibly with additions of quartz sand and feldspar, until sintering or melting. Heat shield stones, which have at least aluminum oxide and aluminum silicate, are easily adaptable with regard to the grain size in the hot side area and in the wall side area and with regard to the concentration proportions of the two substances.

In this case, the mullite content can be compared to the aluminum oxide content be less in the wall side area than in Hot-side region. The mullite portion can preferably be in the wall side region be significantly smaller than the aluminum oxide content. In particular, the aluminum oxide content in the wall side area the dominant part in the composition of the Heat shield stone. The wall side area can be further preferred predominantly made of aluminum oxide, particularly practical consist exclusively of aluminum oxide. More preferred the mullite content is greater than that in the hot side area Alumina content. Especially in the hot side area the mullite content is so much larger than the alumina content, that especially the mullite portion is the dominant component of the heat shield brick is in the hot side area. In a particularly preferred embodiment, the The hot side area is made almost entirely of mullite.

Advantageously, one according to the above statements preferably designed heat shield brick, with a dominant Mullite content in the hot side area and a dominant Alumina content in the wall side area, high strength in the wall side area with high thermal shock resistance in the hot side area.

In a particularly preferred embodiment, the first is Fabric a ceramic and the second fabric a metal. Thereby can also advantageously have metal heat shield stones, as for example in WO 98/53940 a metal-ceramic gradient material are described, with regard to a grain size adjustment specific to the load range be improved. The concept of the invention is consequently on a variety of different chemical compositions of heat shield stones applicable.

The object directed to a combustion chamber is achieved according to the invention solved by a combustion chamber with an inner combustion chamber lining, the heat shield stones according to the above Has designs.

The object directed to a gas turbine is achieved according to the invention solved by a gas turbine with such heat shield stones having combustion chamber.

The advantages of such a combustion chamber and such a gas turbine arise in accordance with the explanations for the heat shield stone.

FIG 1

in perspektivischer Darstellung einen Hitzeschildstein,

FIG 2

eine vergrößerte Ansicht der in FIG 1 gezeigten Einzelheit II,

FIG 3

eine analog zu FIG 2 vergrößerte Ansicht der in FIG 1 gezeigten Einzelheit III,

FIG 4

in einem Ausschnitt eine Seitenansicht eines Hitzeschildsteins mit Schichtaufbau,

FIG 5

ein Diagramm mit der Darstellung des Verhaltens der Korngröße des in FIG 4a gezeigten Hitzeschildsteins, und

FIG 6

einen stark vereinfachten Längsschnitt durch eine Gasturbine.

The invention is explained in more detail by way of example with reference to the drawing. They show schematically and partially simplified:

FIG. 1

in perspective a heat shield stone,

FIG 2

2 shows an enlarged view of the detail II shown in FIG. 1,

FIG 3

2 shows an enlarged view of detail III shown in FIG. 1, similar to FIG. 2,

FIG 4

in a detail a side view of a heat shield brick with a layer structure,

FIG 5

4 shows a diagram showing the behavior of the grain size of the heat shield brick shown in FIG. 4a, and

FIG 6

a greatly simplified longitudinal section through a gas turbine.

The same reference numerals have in the different figures same meaning.

1 shows a perspective view of a heat shield brick 1 shown. The heat shield brick 1 has a cuboid shape Geometry on, with a hot side 3 and one of the hot side opposite wall side 5. On the hot side 3 adjoins a hot side area 7. Bordered on wall side 5 a wall side area 9. The hot side area 7 and the Wall side area 9 each extend from the hot side 3 or the wall side 5 into the interior of the cuboid heat shield brick 1. The material from which the heat shield brick 1 is composed, for example a refractory ceramic, points in the wall side area 9 and in the hot side area 7 a respective grain size distribution. Here is the Grain size distribution set so that the grain size on average D is smaller in the wall side area 9 than in the hot side area 7. This structural design of the heat shield brick 1 is the thermomechanical requirements adjusted to specific areas. Especially when used the heat shield brick 1 in a combustion chamber, for example a combustion chamber of a gas turbine are the requirements to the heat shield brick 1 in the hot side area 7 and the wall side area 9 different. With the targeted Grain size adjustment according to the invention can partially competing hot side requirements 7 and in the wall side area 9 equally largely fulfilled and compared to conventionally designed heat shield stones 1 significant improvements can be achieved. This is for example in the wall side area 9 high strength and in the hot side area 9 a special resistance to high Thermal stresses, temperature and temperature changes (Thermal shock resistance) reached. The heat shield stone 1 is therefore for high temperature applications and for one Exposure to a corrosive, hot medium, for example a hot gas, with temperatures up to 1500 ° C, designed.

In order to illustrate the different grain sizes in the hot side area 7 and in the cold side area 9, details II and III are respectively shown in an enlarged illustration in FIGS. 2 and 3. The details X1, X2 are enlarged by approximately the same factor compared to the illustration in FIG. 1. 2 shows the detail II, ie an enlarged section of the hot side area 7 of the heat shield brick 1. The hot side area 7 has a grain structure with a large number of grains 21, 23 adjoining one another. The ensemble of a large number of grains 21, 23 can be examined with regard to the grain size D, ie the grain size diameter. The grain size in the hot side area 7 has an average size D _H. For comparison, FIG. 3 shows detail III of a grain structure as set in the wall side area 9 of the heat shield brick 1 according to the invention. The grain structure in the wall side area 9 has a multiplicity of grains 25, 27 which adjoin one another and form a structure in the wall side area 9. The grain size D _W in the wall side area 9 is smaller than the grain size D _H in the hot side area 7.

4 shows sections of a schematic side view of a heat shield stone 1. In this context, FIG also pointed out for better comparison. Along a direction 13 from the hot side 3 to the wall side 5 of the Heat shield stones 1, layers 11A to 11F are provided. The hot side area 7 comprises one of the hot side 3 assigned layer 11A, while the wall side region 9 a comprises the layer 11F assigned to the wall side 5. The heat shield stone 1 is made of at least two substances 17, 19 composed, a first substance 17 and a different one second substance 19 built into the heat shield brick 1 is.

5 shows a diagram which graphically illustrates the average grain size D along the direction 13 from the hot side 3 to the wall side 7 (vertical axis). The layer sequence of the layers 11A to 11F is illustrated along the direction axis 13. The grain size D is plotted along the axis 15 (horizontal axis). The heat shield brick 1 has a grain size D _H in the hot side region 7 comprising the layer 11A. In the wall side region 9 comprising the layer 11F, the heat shield brick 1 has an average grain size D _W. The grain size D _{W is} smaller than the grain size D _H. Furthermore, a respective grain size D is set in the intermediate layers 11B to 11E lying between the layer 11A and the layer 11F. The grain size D decreases accordingly in layers from the hot side 3 to the wall side 5. Thus, along the direction 13 from the hot side 3 to the wall side 5, a gradual, in particular step-like, adaptation of the grain size D is achieved, which also means the relevant material properties of the heat shield brick 1, for example strength, thermal conductivity, ductility, etc. are gradually coordinated accordingly. This avoids abrupt changes in properties and considerably increases the resilience and efficiency of the material forming the heat shield brick 1.

5 shows possible variants for the course of the grain size D as a function of the layer sequence 11A to 11F are shown in simplified form. The curve T ₁ provides an image of a gradual, in particular step-like, adaptation of the grain size D from the smaller grain size D _W to the larger grain size D _H , as is set in each of the areas 7, 9. With a corresponding number of layers 11A to 11F, however, it is also possible to change the adaptation of the grain size D along a direction 13 from the hot side 3 to the wall side 9 by means of a continuous, or at least a quasi-continuous function. A further curve T _{2 is} shown in the diagram in FIG. 5 to illustrate this fact. The curve T ₂ represents a linear adaptation along the direction axis 13. Here, the grain size D is changed linearly from D _H to D _W from the hot side region 7 to the wall side region 9 along the direction axis 13. In addition to the curves T ₁ and T ₂ , other adjustments of the grain size D along the direction axis 13 are also possible. This enables adjustments using higher-order polynomials or optionally other continuous or continuously differentiable functions. This is dependent on the load case and can be adapted in each case depending on the thermomechanical requirements for the heat shield brick 1.

In addition to the adjustment of the grain size D, an adjustment of the concentrations of the chemical constituents, namely the first substance 17 and the second substance 19 in the heat shield brick 1, can be set, in particular in the case of a two-substance mixture. This combination of structural and chemical adaptation of the heat shield brick 1 makes it possible, in particular, to achieve high thermal shock resistance in the hot side area 7 and high strength in the wall side area 9. For example, aluminum oxide Al ₂ O ₃ is used as the first substance 17, while mullite is used as the second substance 19. The concentration of the first substance 17 and / or the second substance 19 can change along the direction axis 13 from the wall side 3 to the hot side 5 in a manner adapted to the load.

When used in a gas turbine, for example, the hot side 3 is exposed to a hot, aggressive medium, the hot gas, and the concentration of the first substance 17, for example aluminum oxide Al ₂ O ₃ , is set greater in the wall side area 9 than in the hot side area 7. In the hot side region 7, the concentration of the second substance 19, for example mullite, is greater than the concentration of the first substance 17 (for example aluminum oxide Al ₂ O ₃ ). For example, in a two-substance mixture, the concentration of the first substance 17, for example aluminum oxide Al ₂ O ₃ , in the wall side region 9 can be almost 100%, while in the hot side region 7 the concentration of the second substance 19, for example mullite, is almost 100%.

6 shows a highly schematic and simplified in one Longitudinal section of a gas turbine 31. Along a turbine axis 33 are arranged in succession: a compressor 35, a combustion chamber 37 and a turbine part 39. The combustion chamber 37 is lined with a combustion chamber lining 41 on the inside. The combustion chamber 37 has a combustion chamber wall 43 on. A support structure 45 is through the combustion chamber wall 43 educated. The combustion chamber 37 has heat shield stones 1, 1A, 1B according to the above statements. Here are the heat shield stones 1, 1A, 1B with its wall side 5 of the support structure 45 facing the support structure 45 by means of suitable, not fasteners shown attached. Operational the gas turbine 31 are the heat shield stones 1, 1A, 1B at least with their respective hot side 3 of a hot one Medium M, the hot gas of the gas turbine. Just a gas turbine 31 can cause considerable vibrations about coming from combustion chamber hum. In the event of a resonance even shock-like acoustic combustion chamber vibrations large vibration amplitudes occur. These vibrations lead to considerable stress on the combustion chamber lining 41. Both the support structure 45 and the heat shield stones 1, 1A, 1B affected. By bumps especially the heat shield stones 1A, 1B are endangered, in particular because of the existing risk of breakage. They are further Heat shield stones 1, 1A, 1B are particularly thermally stressed, especially on the one charged with the hot gas M. Hot side 3. Due to the design of the heat shield stones 1, 1A, 1B with an area-specific load-appropriate setting grain size D, preferably also with a variation in the chemical composition of one Dual-substance system, is a customized to the requirements Heat shield brick 1, 1A, 1B installed in the combustion chamber 37. This results in a particularly high level of insensitivity to the Combustion chamber lining 41 against shocks or vibrations or temperature load, in particular temperature change load.

Claims (14)

Heat shield brick (1, 1A, 1B), in particular for lining a combustion chamber wall (43), with a hot side (3) which can be exposed to a hot medium (M) and a wall side (5) opposite the hot side (3), and with one on the hot side (3) adjacent hot side area (7) and a wall side area (9) adjacent to the wall side (5),
characterized in that the grain size (D) in the wall side area (9) is smaller on average than in the hot side area (7). Heat shield brick (1, 1A, 1B) according to claim 1,
characterized in that the grain size (D) in the wall side area (9) is about a factor of 0.4 to 0.9, in particular a factor of 0.6 to 0.8, smaller than in the hot side area (7). Heat shield brick (1, 1A, 1B) according to claim 1 or 2,
characterized in that on average the grain size (D) in the hot side area (7) is between approximately 1.5 mm and 3.5 mm, in particular larger than approximately 2 mm. Heat shield brick (1, 1A, 1B) according to claim 1, 2 or 3,
characterized in that the grain size (D) in the wall side area (9) is between approximately 0.6 mm and 1.4 mm, in particular smaller than approximately 1.2 mm. Heat shield brick (1, 1A, 1B) according to one of the preceding claims,
characterized in that layers (11A, 11B, 11C) with decreasing grain size (D) are provided along a direction (13) from the hot side (3) to the wall side (5). Heat shield brick (1, 1A, 1B) according to claim 5,
characterized in that the number of layers (11A, 11B, 11C) is approximately 5 to 30, in particular approximately 10 to 20. Heat shield brick (1, 1A, 1B) according to one of claims 1 to 4,
characterized in that the grain size (D) changes essentially continuously along a direction (13) from the hot side (3) to the wall side (5). Heat shield brick (1,1A, 1B) according to one of the preceding claims,
characterized in that it is composed of at least two substances (17, 19), with a first substance (17) and a different second substance (19). Heat shield brick (1, 1A, 1B) according to claim 8,
characterized in that the concentration of the first substance (17) in the wall side area (9) is greater than in the hot side area (7). Heat shield brick (1, 1A, 1B) according to one of claims 8 or 9,
characterized in that the first substance (17) is an oxide and the second substance (19) is a silicate, in particular a silicate ceramic. Heat shield brick (1, 1A, 1B) according to one of claims 8 to 10,
characterized in that the first substance (17) is aluminum oxide Al ₂ O ₃ and the second substance (19) aluminum silicate 3Al ₂ O ₃ · 2SiO ₂ . Heat shield brick (1, 1A, 1B) according to claim 8 or 9,
characterized in that the first material (17) is a ceramic and the second material (19) is a metal. Combustion chamber (37) with an internal combustion chamber lining, the heat shield stones (1, 1A, 1B) according to one of the preceding Claims. Gas turbine (31) with a combustion chamber (37) according to claim 11th

Images