EP1508761A1 - Thermal shielding brick for lining a combustion chamber wall, combustion chamber and a gas turbine - Google Patents

Abstract

A gas turbine combustion chamber has a heat shield tile with a core surrounded by an edge capping material. The heat conductivity of the edge capping material is lower than that of the ceramic core material. Also claimed is a gas turbine engine combustion chamber with a heat shield and a commensurate gas turbine engine.

Description

The invention relates to a heat shield brick, in particular for Lining of a combustion chamber wall, with one of a hot Medium act on hot side and one of the hot side opposite Wall side and with one from the hot side to the wall side extending core area with a Core material. The invention further relates to a combustion chamber with an inner combustion liner and a gas turbine.

A thermally and / or thermomechanically highly loaded combustion chamber, such as a kiln, a hot gas duct or a combustion chamber in a gas turbine, in which a hot medium is generated and / or out, is too high for protection thermal stress with a corresponding lining Mistake. The lining is usually made heat-resistant material and protects a wall of the combustion chamber before direct contact with the hot medium and the associated strong thermal load.

US Pat. No. 4,840,131 relates to an attachment of ceramic lining elements on a wall of a furnace. Here is a rail system which is attached to the wall is. The lining elements have a rectangular shape with a planar surface and consist of a heat-insulating, refractory, ceramic fiber material.

U.S. Patent 4,835,831 also deals with application a refractory lining from a wall of a Furnace, in particular a vertically arranged wall. On the metallic wall of the furnace becomes one of glass, ceramic, or mineral fibers existing layer applied. These Layer is attached by metallic clips or by adhesive attached to the wall. On this layer is a wire mesh with .... applied meshes. The mesh also serves securing the layer of ceramic fibers against Falling. In addition, it is fastened by means of a bolt a uniform closed surface of refractory material applied. With the described method is largely avoided that impinging during spraying refractory particles are thrown back, as with a direct spraying of the refractory particles on the metallic wall would be the case.

A ceramic lining of the walls of thermally highly stressed combustion chambers, for example of gas turbine combustion chambers, is described in EP 0 724 116 A2. The lining consists of wall elements made of high temperature resistant structural ceramic, such. As silicon carbide (SeC) or silicon nitrite (Si ₃ N ₄ ). The wall elements are mechanically fixed by means of a central fastening bolt to a metallic support structure (wall) of the combustion chamber. Between the wall element and the wall of the combustion chamber, a thick thermal insulation layer is provided, so that the wall element is spaced correspondingly from the wall of the combustion chamber. About three times as thick in relation to the wall element insulation layer consists of ceramic fiber material, which is prefabricated in blocks. The dimensions and the external shape of the wall elements are adaptable to the geometry of the space to be lined. Another type of lining of a thermally highly loaded combustion chamber is given in EP 0 419 787 B1. The lining consists of heat shield elements, which are mechanically supported on a metallic wall of the combustion chamber. The heat shield elements touch the metallic wall directly. To avoid excessive heating of the wall, z. B. as a result of direct heat transfer from the heat shield element or by penetration of hot medium into the gaps formed by the adjacent heat shield elements, the space formed by the wall of the combustion chamber and the heat shield element with cooling air, the so-called sealing air is applied. The blocking air prevents the penetration of hot medium up to the wall and at the same time cools the wall and the heat shield element.

WO 99/47874 relates to a wall segment for a combustion chamber and a combustion chamber of a gas turbine. This is a Wall segment for a combustion chamber, which with a hot Fluid, e.g. As a hot gas, can be acted upon, with a metallic Support structure and one on the metallic support structure attached heat shield element specified. Between the metallic support structure and the heat shield element is a deformable separating layer inserted, the possible relative movements receive the heat shield element and the support structure and compensate. Such relative movements can for example, in the combustion chamber of a gas turbine, in particular an annular combustion chamber, by different thermal expansion behavior the materials used and pulsations in the combustion chamber, during an irregular combustion for generating the hot working medium under the resonance effects may arise. At the same time causes the release layer that the relatively inelastic heat shield element total area on the release layer and the metallic support structure rests, since the heat shield element partially penetrates into the separation layer. The separation layer can thus production-related bumps on the support structure and / or the heat shield element that is local to one unfavorable punctual force entry, balance.

Especially in the case of walls of high-temperature gas reactors, such as z. Pressurized gas turbine combustors, have their bearing with suitable combustion chamber liners Protected structures against a hot gas attack. ceramic Materials are available in comparison to metallic ones Materials due to their high temperature resistance, Corrosion resistance and low thermal conductivity ideally. Because of material-typical thermal expansion properties under operating conditions typically occurring Temperature differences (ambient temperature at standstill, maximum temperature at full load) must have the thermal mobility ceramic heat shields as a result of temperature-dependent Elongation guaranteed, so no component destructive Thermal stresses due to expansion inhibition occur. This can be achieved by the hot gas attack before protective wall by a variety of limited in size, individual ceramic heat shields, z. B. heat shield stones from a Feuerfestkeramik, is lined. As already discussed above in connection with EP 0 419 487 B1, must be between the individual ceramic heat shield elements appropriate expansion gaps are provided for safety reasons, even in hot conditions never be completely closed. It must be ensured be that the hot gas does not have the expansion column the load-bearing wall structure overheated. The easiest and safest way to do this in a gas turbine combustor too Avoid, is doing the rinsing of the expansion column with air, so called blocking air cooling. The air can be used for this purpose be, anyway for cooling of support elements for the ceramic heat shield is required.

In WO 02/25173 A1 is a heat shield brick, in particular for lining a combustion chamber wall, with a hot one Medium exposable hot side, one of the hot side opposite Wall side and one to the hot side and the wall side adjacent peripheral side having a peripheral side surface has disclosed. On the peripheral side is a circumferential direction provided Zugelement provided, wherein a Compressive stress is generated normal to the peripheral side surface. This will be a highly efficient and long-term stable Fuse specified for a heat shield brick. The tension element is biased in the circumferential direction, with a certain Compressive stress is generated normal to the peripheral side surface. By this normal force, pointing towards the inside of the heat shield stone in the center of which is directed becomes the heat shield stone already secured at very low normal forces. As a result, a material tear, for example in Consequence of a shock load, effectively counteracted. Existing material cracks can occur with appropriate arrangement and embodiment of the tension element not or only limited continue education or expand. The tension element stops The heat shield brick, so to speak together and secures him on the one hand against Materialanrissen and on the other hand especially against a complete material tear. additionally becomes the danger of detachment or falling out of smaller or larger fragments in case of a possible Material tear effectively countered.

The object of the invention is to specify a heat shield block, which both in terms of unlimited thermal Expansion as well as in terms of its resistance a hot gas attack high reliability and long service life guaranteed. Another object of the invention is the specification of a combustion chamber with an inner Combustion lining and the specification of a gas turbine with a combustion chamber.

The object directed to a heat shield brick is achieved according to the invention solved by a heat shield stone, in particular for lining a combustion chamber wall, with one of a hot medium acted upon hot side and one of the hot side opposite wall side, and with one of the hot side to the wall side extending core area with a core material, wherein the core portion of a peripheral region surrounded by a marginal material whose thermal conductivity lower than that of the core material.

The invention already starts from the knowledge, that in case of use in consequence of the edges of the heat shield stone cooling air flow through the gap between the Heat shields and the heat input to the hot side of the Heat shield block as a result of the application of hot gas, a three-dimensional temperature distribution within the Heat shield stone sets. This is marked by a Temperature drop from the hot side to the wall side and in Consequence of the sealing air cooling of the edges ("edge cooling") of central points in the ceramic heat shield stone towards the cooled edges. At typically parallel to the hot side or to the wall side flat heat shields leads the temperature gradient perpendicular to the wall surface for comparison only low thermal stresses, so long for the heat shield brick in the installed state no obstruction the thermally-induced bulge exists. On the other hand leads a parallel to the wall temperature gradient - starting from an edge to an inner area of the heat shield stone - due to the mechanical rigidity of plate-like Geometries with respect to deformations parallel to their Size projection surfaces particularly easy to increased thermal voltages. Cold edges are thereby in consequence of their comparatively low thermal expansion of hotter central regions, subjected to a greater thermal expansion are put under train and can be exceeded the material strength for cracking, starting from the Edges of the heat shield stone, lead.

With the invention now a completely new concept is shown, in particular a failure of the heat shield stone in Consequence of the cracking problem, starting from the edges of the Heat shield stone, to avoid. The invention is doing it exploit the knowledge that thermally induced tensile stresses usually only occur where temperature gradients available. Is now prevented from the Edges of the heat shield brick outgoing temperature gradients penetrate deeply into the interior of the heat shield stone, so can As a result, cracks only partially penetrate or do not even form. It can be short, from the edges Outgoing cracks that are only slightly in the direction of the inner penetrate the heat shield, be tolerated, as these the functioning of the heat shield stone theoretically as well even in practical experience.

The invention provides a heat shield brick, whose thermal conductivity is set locally targeted to To avoid cracking and crack growth. For this is the Core area surrounded by a marginal area with a marginal material, whose thermal conductivity is lower than that of Core material. So it's going to be a two-material heat shield stone indicated with a thermal insulation in the edge area, due to the specific choice of material for the edge material, with towards the core material reduced thermal conductivity. The core area and the edge area are integral components of the heat shield stone, leaving a heat shield stone with over its volume of variable thermal conductivity is provided. Due to the greater thermal conductivity in the Core area is achieved that in the core area a parallel to the hot side approximately balanced temperature profile established. The core area thus remains largely heat stress. Temperature gradients and associated therewith Thermal stresses occur only in the edge area.

The edge region advantageously also includes the outer edges of the heat shield stone, so this due the opposite to the core area lower thermal conductivity act as a thermal insulation or as an isolation area. Of particular advantage here is that the length of thermo-voltage induced Cracks is shortened because these on the Edge area are limited, whereby the heat shield brick respect a cracking is stabilized.

In a preferred embodiment of the heat shield brick the thermal conductivity of the edge material is less than 60%, in particular less than 50% of the thermal conductivity of the core material. The heat shield stone is thus designed that a significant reduction in the thermal conductivity at the transition from the core area to the edge area.

The edge area acts as a thermal insulation, the surrounds the core area. Advantageously encloses the Edge region of the core area directly, with a cohesive Composite of the core material and the edge material is realized.

Preferably, the edge material is porous, wherein the porosity of the edge material is set specifically so that As a result, the thermal conductivity of the edge material opposite the thermal conductivity of the core material is lowered. about the density distribution and size distribution of the pore structure of the edge material can in the edge region the thermal conductivity depending on the requirements in case of load targeted become. It may also be possible within the Edge region a variation of local thermal conductivity via a corresponding variation of the pore size and pore diameter distribution be achieved.

In a particularly preferred embodiment, the core material and the edge material of the same ceramic base material, in particular a refractory ceramic, formed. Through this Material identity of the base material is a special good Material bond between the core material and the edge material achievable. To achieve the desired porous structure within of the edge region, for example, in the production of the heat shield stone the so-called meddling Pore formers be provided in the base material. The pore builder is advantageously in the near-edge region, that is pressed in the edge area of Dröhnlings or poured. During the Sinther process volatilized itself the pore builder and leaves the pores that the effective Thermal conductivity of the base material accordingly Lower. In the core area, this pore-forming agent is preferred not applied, so that the desired reduction in thermal conductivity in the transition from core area to the edge area results.

In an advantageous embodiment, along the hot side of the Heat shield the axial extent of the edge region less than 20%, in particular between about 5 and 10%, the axial total extension of the heat shield stone. Especially The heat shield stone is covered at all of the edge area Edges with deviating from the core material low thermal conductivity at a distance of less than 10% of the respective Total extension (carrying length) with a lowering of the thermal conductivity opposite the thermal conductivity of the core area provided on less than 50% of the core material.

Preferably, the edge region extends from the hot side the wall side. In this embodiment, the core area Completely enclosed by the peripheral area, so that a full-scale thermal insulation of the core area under realization of a material bond between nuclear material and edge material is reached.

Preferably, the heat shield brick on the hot side and the wall side adjacent peripheral side having a peripheral side surface on, at least partially from the edge material is formed. In one for the evaluation of a combustion chamber wall required arrangement of a variety of heat shield bricks are the gaps between the heat shield stones thereby at least partially from the edge material on the peripheral side surface limited. Advantageously, the peripheral side surface completely formed by the core material, so that the best possible thermal insulation of Core material is given.

Preferably, the heat shield brick consists of a ceramic Base material, in particular of a refractory ceramic. By the choice of a ceramic as a base material for the heat shield stone is the use of heat shield stone up to very high Temperatures safely ensured while being oxidative and / or corrosive attacks, as in the event of an attack the hot side of the heat shield brick with a hot medium, z. B. a hot gas, largely harmless for are the heat shield stone. This is of great advantage when using the heat shield brick in a combustion chamber, because even after a crack of the material in the edge area the heat shield function of the heat shield continues to be guaranteed is, in particular, a failure of the heat shield stone, for example, a complete break, sure avoided, so that no fragments in the combustion chamber can reach.

Economically, this results in the advantage of that in normal operation no extraordinary maintenance and / or revision of a heat shield brick having Combustion chamber is required. On the other hand, the heat shield stone has in case of special occurrences of emergency running characteristics, so that consequential damage to a turbine, for example can be avoided for blading because by the targeted adjustment of the thermal conductivity in different Areas of the heat shield stone a crack propagation is largely avoided.

The combustion chamber can, at least with the usual maintenance cycles be operated, but also an extension of the Service life due to the lower tendency to crack propagation is achievable.

The task directed to a combustion chamber is according to the invention dissolved by a combustion chamber with an inner combustion liner, the heat shield stones according to the above Executions has.

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

The advantages of such a combustion chamber or such Gas turbine arise in accordance with the comments on the Heat shield block.

Figur 1

einen Halbschnitt durch eine Gasturbine,

Figur 2

in einer perspektivischen Darstellung ein Hitzeschildstein,

Figur 3

eine Schnittansicht des in der Figur 2 gezeigten Hitzeschildsteins entlang der Schnittlinie III-III.

Figuren 4 bis Figur 7

verschiedene Ausgestaltungen eines Hitzeschildsteins mit einem Kernbereich und mit einem Randbereich.

The invention will be explained in more detail by way of example with reference to the drawings. It shows schematically and partially simplified:

FIG. 1

a half-section through a gas turbine,

FIG. 2

in a perspective view a heat shield stone,

FIG. 3

a sectional view of the heat shield brick shown in Figure 2 along the section line III-III.

FIGS. 4 to 7

various embodiments of a heat shield stone with a core area and with a border area.

Identical parts are given the same reference numerals in all figures Mistake.

The gas turbine 1 according to FIG. 1 has a compressor 2 for Combustion air, a combustion chamber 4 and a turbine 6 for Drive of the compressor 2 and a generator, not shown or a work machine. These are the turbine 6 and the compressor 2 on a common, as a turbine rotor designated turbine shaft 8 is arranged, with the also the generator or the work machine is connected, and which is rotatably mounted about its central axis 9. In the the type of an annular combustion chamber running combustion chamber 4 is with a number of burners 10 for burning a liquid or gaseous fuel.

The turbine 6 has a number of with the turbine shaft. 8 connected rotatable blades 12. The blades 12 are arranged in a ring on the turbine shaft 8 and thus form a number of blade rows. Farther The turbine 6 includes a number of stationary vanes 14, which is also coronal under the formation of Guide vane rows attached to an inner housing 16 of the turbine 6 are. The blades 12 serve to drive the turbine shaft 8 by momentum transfer from the turbine. 6 flowing through hot medium, the working medium M. The vanes 14, however, serve to guide the flow of the working medium M between each two in the flow direction of the Working medium M seen, consecutive blade rows or blade wreaths. A successive one Pair of a ring of vanes 14 or a row of vanes and from a wreath of blades 12 or a blade row is also referred to as a turbine stage.

Each vane 14 has a so-called blade root Platform 18 on, which fixes the respective vane 14 on the inner housing 16 of the turbine 6 as a wall element is arranged. The platform 18 is a thermal comparatively heavily loaded component, which is the outer boundary a hot gas channel for the turbine 6 flowing through Working medium M forms. Each blade 12 is analogous via a platform 20, also referred to as a blade root attached to the turbine shaft 8.

Between the spaced apart platforms 18 of the vanes 14 of two adjacent rows of vanes in each case a guide ring 21 is arranged. The outer one Surface of each guide ring 21 is also the hot, the turbine 6 flowing through working medium M exposed and in the radial direction from the outer end 22 of it opposed blade 12 spaced by a gap. The arranged between adjacent vane rows Guide rings 21 serve in particular as cover elements, the inner wall 16 or other housing-mounting parts before a thermal overload by the the turbine 6 through flowing hot working medium M protects. The combustion chamber 4 is bounded by a combustion chamber housing 29, wherein combustion chamber side a combustion chamber wall 24 is formed is. In the exemplary embodiment, the combustion chamber 4 as so-called annular combustion chamber designed in which a variety arranged circumferentially about the turbine shaft 8 around Burners open in a common combustion chamber space. For this purpose, the combustion chamber 4 in its entirety as an annular Structure designed around the turbine shaft. 8 is positioned around.

To achieve a comparatively high efficiency the combustion chamber 4 for a comparatively high temperature the working medium M of about 1200 ° C to 1500 ° C designed. Even with these, for the materials unfavorable operating parameters to allow a comparatively long service life is the combustion chamber wall 24 on the working medium M facing side with a heat shield bricks 26th provided combustion chamber lining provided. For a hot gas resistant Structure of designed as an annular combustion chamber Combustion chamber 4 is the combustion chamber lining with a plurality provided by high temperature resistant heat shield stones 26, so that in this way a full-surface, largely leak-free Combustor lining is formed in the annulus.

FIG. 2 shows a heat shield block 26 in a perspective view, as he especially for lining a combustion chamber wall 24 is designed according to the invention. The combustion chamber stone 26 has a cuboid or parallelepiped-like geometry and extends along a longitudinal axis 43 and a substantially perpendicular to the longitudinal axis 43 extending Transverse axis 45. The heat shield block 26 has one of the hot medium M acted upon hot side 35 and one of Hot side 35 opposite wall 33 on. Of the Hot side 35 to the wall side 33 extends through the interior of the heat shield block 26, a core portion 31 with a Core material 39. The core region 31 is from a peripheral region 37 surrounded with a border material 41, wherein the thermal conductivity of the edge material 41 is lower than the thermal conductivity of the core material 39. The edge region 37 encloses the core region 31 completely along the edges of the cuboid or cuboid heat shield element 26. The Material transition from the core material 39 in the core region 31 to the edge material 41 in the edge region 37 is effected by a Adhesive bond. The thermal conductivity of the edge material 41 is less than 50% of the thermal conductivity of the core material 39. This ensures that when using the heat shield stone 26 in the combustion chamber 4 of a gas turbine 1 (see. Figure 1) in the core area parallel to the hot side 35th sets approximately balanced temperature profile. Of the Core area 31 remains in consequence of the thermal insulation effect the edge region 37 with the lowered thermal conductivity largely free of heat stress. Temperature gradients and Consequently, associated thermal stresses occur only or almost exclusively in the edge area 37, that is near the Edges of the heat shield block 26 on. Thus, the length of thermo-cracks shortened, on the edge area 31 limited and the heat shield brick 26 in total with respect Cracking and crack propagation over conventional designs stabilized.

FIG. 3 shows a sectional view along the section line III-III of the heat shield block 26 shown in FIG. Here is a view of the heat shield brick 26 in the direction the transverse axis 45 shown on the cutting surface. The core area 31 is cuboid or parallelepiped-like. The border area 37 completely surrounds the core region 31 with itself the edge portion 31 from the hot side 35 to the wall side 33 extends. The edge region 37 consists of a border material 41, wherein the peripheral side surface 49, the edge material 41st having. The peripheral side surface 49 is the outermost Boundary surface of the peripheral side 47, which on the hot side 35 and adjacent to the wall 33. To adjustment a reduced thermal conductivity in the edge region 41 opposite the core portion 31 is the edge material 41 as a porous Material configured with a variety of pores, wherein the Porosity of the edge material 41 is set specifically, that thereby the thermal conductivity of the edge material 41st to the thermal conductivity of the core material 39 on a desired level is lowered. The thermal conductivity of the Edge material 41 is for example less than 60%, in particular less than 50% of the thermal conductivity of the core material 39. In this case, the core material 39 and the edge material 41, for example, from the same ceramic base material, in particular a refractory ceramic, be formed. By this substance identity of the base material for the core material 39 and the edge material 41 is a particularly solid and durable material composite realized.

The setting of a desired porosity for lowering the thermal conductivity in the edge region 37 takes place, for example, by mixing suitable pore formers into the ceramic mass, the pore formers being pressed or cast into the edge region 37 of the drone being defined by the edge region 37. During the sintering process, the pore-forming agent volatilizes and leaves behind pores having a predetermined pore diameter distribution and pore density distribution within the edge region 37. The heat-shielded brick 26 thus becomes in edge region 37 with lower thermal conductivity deviating from the core material 39, for example with a reduction in the thermal conductivity to less than 50% of the core material 39 provided. In this case, along the hot side 35, the axial extent d _{R of} the edge portion 37 is less than 20%, in particular between about 5% and 10% of the total axial extent L of the heat shield block 26. Consequently, in this embodiment, the axial extent d _{K of} the core portion 31 with the Core material 39 significantly larger than the axial extent d _{R of} the edge region 37. The advantages of the core material 39 in the core region 31 in terms of resistance to high temperature load and exposure to a hot medium M, such as a hot gas, thus largely retained, with cracking in particular on the hot side 35 in the core region 31 is largely suppressed by the thermal insulation effect of the porous edge material 41 even at high temperature load or thermal cycling. A possible cracking or crack propagation can possibly occur in edge area 37, where this is tolerable.

FIGS. 4 to 7 show further embodiments of the heat shield block 26 with modification of the geometry of the heat shield stone 26 (see Figures 6 and 7) or with variation of Geometry of core area 31 and edge area 37. In one FIG. 4 shows a sectional view of a heat shield element 26 with a extending from the hot side 35 to the wall 33 side Edge region 37, wherein the cross section of the edge region 37 imposed on the wall 33 side. Corresponding the cross section of the core region 31 decreases from the hot side 35 to the cold side 33 to continuously. In contrast, Figure 5 shows an embodiment of the heat shield stone 26, in which the edge region 37 with the edge material 41 a Partial surface of the peripheral side surface 49 forms. The border area 37 faces the hot side 35 and is at the same time a component the hot side 35. The peripheral side surface 49 has both the core material 39 and the edge material 41, wherein the edge material 41 faces the hot side 35 and the core material 39 faces the wall side 33. Depending on Application-typical load case for the heat shield stone 26, both the geometry of the edge region 37 and the Core area 31 as well as the local heat conduction properties in the edge area 37 by setting a corresponding Porosity of the edge material 41 in the edge region 37 modified and adapted.

FIGS. 6 and 7 show different geometries of the Heat shield stone 26 in a plan view of the hot side 35. In both embodiments, the geometry of the Core portion 31 is substantially cylindrical and extends from the hot side 35 to the cold side 33. The outer boundary edge of the heat shield element 26 is shown in FIG square geometry and in Figure 7 of hexagonal geometry. The edge region 37 results essentially as Complementary volume to the cylindrical core portion 31. For thermal insulation, the edge material 41 has a porosity on, so that in the edge region 37 a against the Core area 31 significantly reduced thermal conductivity achieved is. The core material 39 and the edge material 41 are of identical base material or substantially the same Base material built so that the transition from the core area 31 to the edge region 37 in the form of a cohesive, is achieved largely homogeneous composite material, the Although chemically identical or similar, but due to the physical Effect of the specifically set porosity of the Edge material 41, the desired reduction in thermal conductivity caused from the core portion 31 to the edge portion 37.

Claims (10)

A heat shield brick (26), in particular for lining a combustion chamber wall (24), with a hot side (35) which can be acted upon by a hot medium (M) and a wall side (33) opposite the hot side (35), and with a side facing away from the hot side (35 ) to the wall side (33) extending core portion (31) having a core material (39),
characterized in that the core region (31) is surrounded by an edge region (37) with a marginal material (41) whose thermal conductivity is lower than that of the core material (39). Heat shield brick (26) according to claim 1,
characterized in that the thermal conductivity of the edge material (41) is less than 60%, in particular less than 50%, of the thermal conductivity of the core material (39). A heat shield brick (26) according to claim 1 or 2,
characterized in that the edge material (41) is porous, wherein the porosity of the edge material (41) is adjusted specifically so that thereby the thermal conductivity of the edge material (41) relative to the thermal conductivity of the core material (39) is lowered. Heat shield brick (26) according to claim 3,
characterized in that the core material (39) and the edge material (41) are formed from the same basic ceramic material, in particular a refractory ceramic. Heat shield brick (26) according to one of claims 1 to 4,
characterized in that the core material (39) and the edge material (41) form a cohesive composite material. Heat shield brick (26) according to one of claims 1 to 5,
characterized in that along the hot side (35), the axial extent (d _R ) of the edge region (37) is less than 20%, in particular between 5% and 10% of the total axial extent (L). Heat shield brick (26) according to one of claims 1 to 5,
characterized in that the edge region (37) extends from the hot side (35) to the wall side (33). Heat shield brick (26) according to one of claims 1 to 7,
characterized in that a peripheral side (47) adjacent to the hot side (35) and the wall side (33) has a peripheral side surface (49) at least partially formed by the skirt material (41). Combustion chamber (4) with an inner combustion chamber lining, the heat shield bricks (26) according to any one of the preceding claims having. Gas turbine (1) with a combustion chamber (4) according to claim 9.

Images