EP1319154A1 - Heat-shield brick, combustion chamber comprising an internal combustion chamber lining and a gas turbine - Google Patents

Abstract

The invention relates to a heat-shield brick (1), in particular for lining a combustion chamber wall, comprising a hot side (3) that can be exposed to a hot medium, a wall side (5) that lies opposite said hot side (3) and a peripheral side (7) that lies adjacent to the hot side (3) and the wall side (5) and that has a peripheral lateral face (9). A tensioning element (11), pre-stressed in the peripheral direction is provided on the peripheral side (7), whereby a compressive stress is generated perpendicularly to the peripheral lateral face. The invention also relates to a combustion chamber comprising a combustion chamber lining, which has heat-shield bricks of this type and to a gas turbine comprising a combustion chamber.

Description

Heat shield brick, combustion chamber with an internal combustion chamber lining and gas turbine

The invention relates to a heat shield block, in particular for lining a combustion chamber wall, with a hot medium can be exposed to the hot side, one of the hot wall side opposite and adjacent to the hot side and the wall side "peripheral side having a peripheral side surface. ^{_'The', ''} invention relates to further comprising a combustion chamber with an _interior; combustor liner and a gas turbine ^•.

A thermally and / or thermomechanically highly loaded combustion chamber, such as a furnace, a hot gas duct or a combustion chamber of a gas turbine, in which a hot medium is generated and / or guided, is provided with a suitable lining to protect it from excessive thermal stress. The lining usually consists of heat-resistant material and protects a wall of the combustion chamber from direct contact with the hot medium and the associated strong thermal stress.

US Pat. No. 4,840,131 relates to fastening ceramic lining elements to a wall of an oven. Here, a rail system, which is fastened to the wall and has a plurality of ceramic rail elements, is provided. Thanks to the rail system, the lining elements can be held on the wall. Additional ceramic layers can be provided between a lining element and the wall of the furnace, including a layer of loose, partially compressed ceramic fibers, this layer having at least approximately the same thickness as the ceramic lining elements or a greater thickness. 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 the application of a refractory lining to a wall of an oven, particularly a vertically arranged wall. A layer of glass, ceramic or mineral fibers is applied to the metal wall of the furnace. This layer is attached to the wall using metal clips or glue. A wire mesh network with honeycomb-shaped meshes is fanned out on this layer. The mesh network also serves to secure the layer of ceramic fibers against falling. Using a suitable spraying method, a uniform, closed surface made of refractory material is applied to the layer thus fastened. The method described largely avoids that refractory particles striking during spraying are thrown back, as would be the case if the refractory particles were sprayed directly onto the metallic wall.

A ceramic lining of the walls of thermally highly stressed combustion chambers, for example gas turbine combustion chambers, is described in EP 0 724 116 A2. The lining consists of wall elements made of high-temperature-resistant structural ceramics, such as silicon carbide (SiC) or silicon nitride (SiN ₄ ). The wall elements are mechanically and resiliently attached to a metal support structure (wall) of the combustion chamber by means of a central fastening bolt. A thick thermal insulation layer is provided between the wall element and the wall of the combustion chamber, so that the wall element is appropriately spaced from the wall of the combustion chamber. The insulation layer, which is about three times thicker than the wall element, consists of ceramic fiber material that is prefabricated in blocks. The Dimensions and external shape _. the wall elements can be adapted to the geometry of the room to be lined.

Another type of lining for a thermally highly loaded combustion chamber is specified in EP 0 419 487 B1. The lining consists of heat shield elements that are mechanically held on a metallic wall of the combustion chamber. The heat shield elements directly touch the metallic wall. To avoid excessive heating of the wall, e.g. as a result of a direct

Heat transfer from the heat shield element or by introducing 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 is acted upon by cooling air, the so-called sealing air.

The sealing air prevents the penetration of hot medium up to the wall and simultaneously 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. Here, a wall segment for a combustion chamber, which is filled with a hot fluid, e.g. a hot gas, can be acted upon, with a metallic support structure and a heat protection element attached to the metallic support structure. Between the metallic support structure and that

A deformable separating layer is inserted in the heat protection element, which should absorb and compensate for possible relative movements of the heat protection element and the supporting structure. Such relative movements can be caused, for example, in the combustion chamber of a gas turbine, in particular an annular combustion chamber, by different thermal expansion behavior of the materials used or by pulsations in the combustion chamber, which can occur in the event of irregular combustion to generate the hot working medium or by resonance effects. At the same time, the separating layer causes the relatively inelastic heat protection element as a whole lies flat on the separating layer and the metallic support structure, since the heat protection element partially penetrates into the separating layer. In this way, the separating layer can compensate for unevenness in the support structure and / or the heat protection element, which can lead to an unfavorable selective force input locally.

The invention is based on the observation that, in particular ceramic, heat shield stones due to their necessary flexibility with regard to thermal

Extensions are often insufficiently secured against mechanical loads such as shocks or vibrations.

The invention is accordingly based on the object of specifying a heat shield brick which ensures high operational reliability both in terms of unlimited thermal expansion and in terms of stability against mechanical, in particular shock-like, loads. Another object of the invention is to provide a combustion chamber with an internal one

Combustion chamber lining and the specification of a gas turbine with a combustion chamber.

The object directed at a heat shield brick is achieved according to the invention by a heat shield brick, in particular for lining a combustion chamber wall, with a hot side that can be exposed to a hot medium, a wall side opposite the hot side and a peripheral side adjacent to the hot side and the wall side and having a peripheral side surface that a tensile element that is prestressed in the circumferential direction is provided on the circumferential side, a compressive stress being generated normal to the circumferential side surface.

The invention shows a completely new concept, heat shield stones against high accelerations as a result Securing shocks or vibrations permanently. The invention is based on the knowledge that combustion chamber bricks, as are usually used for lining a combustion chamber wall, are excited to corresponding vibrations by stationary and / or transient vibrations in the combustion chamber wall. In this case, in particular in a resonance case, considerable accelerations can occur above a limit acceleration, the heat shield bricks lifting off the combustion chamber wall and subsequently striking again. Such an impact on the solid or partially damped combustion chamber wall leads to very high forces on the heat shield bricks and can lead to considerable damage, for example breakage thereof. In addition, there is the high thermal load on the heat shield brick due to the hot medium being exposed to a hot medium during operation. Cracks can thus occur both on the wall side and on the hot side of the heat shield brick, and there is also the risk of material coming out of the heat shield brick. This leads to a significant one

Reduction of the durability of a heat shield brick, mainly because such cracks can lead to a material breakdown and thus to a break and thus failure of the entire heat shield brick. As a result, there is a risk that fragments will get into the combustion chamber and further components of the combustion chamber or, for example when used in a gas turbine, massively damage the sensitive blading area with turbine blades.

With the proposed heat shield brick with a tension element prestressed on the circumferential side in the circumferential direction, an extremely efficient and long-term stable securing for a heat shield brick is specified for the first time. The tension element is prestressed in the circumferential direction, a certain compressive stress being generated normal to the circumferential side surface. By this normal force, which is directed towards the inside of the heat shield brick in the center, the Heat shield stone already secured with very low normal forces. This effectively counteracts a material crack, for example as a result of a shock load. Existing material cracks cannot develop or expand, or only to a limited extent, if the tension element is arranged and configured accordingly. The tensile element holds the heat shield brick together, so to speak, and secures it on the one hand against material cracks and, on the other hand, above all against a complete material tear through. In addition, there is a risk of

Removing or falling out of smaller or larger fragments effectively counteracts in the event of a possible material tear.

The provision of the tension element on the peripheral side of the heat shield brick advantageously dampens vibrations and / or shock loads with a component normal to the peripheral side surface. With an appropriate design and choice of material for the tension element, the damping constant can be set in accordance with the loads that occur. Such shock loads normal to the circumferential side surface can occur, for example, when several heat shield stones are arranged as a result of the relative movement of adjacent heat shield stones. This damping ensures a longer use of the heat shield brick.

It is particularly advantageous to increase the passive safety of the combustion chamber brick compared to the conventional designs. A material crack or tear is counteracted, and in the event of a tear, the removal of fragments of the combustion chamber brick is largely prevented.

The design of the heat shield brick with the tension element also has the advantage of problem-free prefabrication and simple assembly of the heat shield brick, for example for assembly in one Combustion chamber wall. The tension element is simply attached to the circumferential side and pretensioned in the circumferential direction as required. Separate damping and / or securing elements, as can also be found in conventional heat shield bricks, require a considerably greater assembly and adjustment effort than the heat shield brick of the invention. In the event of a revision, only the heat shield brick may have to be replaced, but not additional securing elements. This high flexibility on the one hand and the achievable

Durability of the heat shield brick, on the other hand, is also of particular advantage from an economic point of view. In particular, inspection or maintenance intervals for the heat shield brick, for example when used in a combustion chamber of a gas turbine, are extended. In the event of a broken heat shield brick, operation for the revision of the system does not have to be stopped immediately because, due to the increased passive safety, continued operation is possible up to the regular revision interval or beyond.

Advantageously, the compressive stress that is generated normal to the circumferential side surface can be adjusted by appropriately pretensioning the tension element.

In a preferred embodiment, the tension element extends at least in regions in the circumferential direction. Due to the respective geometry of the heat shield brick, for example in the form of prisms with a polygonal base, the

Has peripheral side surface, different areas can be formed. So that the pulling element can fully develop its effect in order to increase the passive safety of the combustion chamber brick, it makes sense that the pulling element at least in certain areas, in particular also across areas

Extends circumferential direction. This means that a corresponding compressive stress is generated normal to the circumferential side surface.

A plurality of tension elements are preferably provided. The arrangement and design of the tension elements on the

The circumferential side can be made very flexible by using several tension elements. By using several tension elements, critical areas of the heat shield brick, for example corners or edges, in which a tearing or breakthrough or a removal of any fragments could be expected, can be specifically secured. This further increases the operational safety of the heat shield brick.

In a particularly preferred embodiment, a tension element completely surrounds the peripheral side surface. This configuration ensures a securing normal force on the circumferential side surface over the entire circumference of the heat shield brick. A closed ring closure is achieved, so to speak, with the

Heat shield stone as a whole is advantageously passively secured in an advantageous manner by the forces directed locally into the interior of the heat shield stone. Such a tension element, which completely encloses the peripheral side surface, can guarantee this. Depending on the load case, however, it is also possible to attach a plurality of such tension elements which completely enclose the peripheral side surface.

The tension element preferably encloses the peripheral surface several times. A multiple enclosing the circumferential surface

The tensile element increases the securing effect of the tensile element correspondingly many times, whereby the securing forces directed normally to the circumferential side surface increase. Through this multiple enclosing, the tension element forms, so to speak, a multiple reinforcement of the heat shield brick on the peripheral side. This multiple backup means that achieves particularly high operational reliability with the economic advantages already discussed above.

More preferably, the peripheral side has a peripheral groove in which the tension element engages. The circumferential groove is advantageously formed over the entire circumference on the circumferential side, for example by appropriate material-removing processing of the heat shield brick or by shaping the circumferential groove when producing the heat shield brick from a, for example ceramic, molding compound. The engagement of the tension element in the circumferential groove is a very effective one

Heat shield stone protection reached, the tension element in the circumferential groove being additionally protected against direct exposure to a hot gas, as is provided in the operating case. Furthermore, the circumferential groove forms a fall-out protection for the tensile element or, if several tensile elements are used, for the tensile elements engaging in the circumferential groove. The circumferential groove advantageously extends over the entire circumference of the

Heat shield block. In an alternative embodiment, however, it is also possible that the circumferential groove is not formed over the full circumference of the heat shield brick, but rather only in a selectable partial area on the circumferential side.

Further preferably, at least one further circumferential groove is provided, which is spaced apart from the circumferential groove, a tension element engaging in the further circumferential groove. The circumferential groove can be provided, for example, on the end of the circumferential side facing the hot side of the combustion chamber brick, while the further circumferential groove is provided on the end of the circumferential side facing the wall side. Multiple securing with circumferential grooves, in which at least one tension element engages, is hereby ensured, the advantages mentioned for a circumferential groove being correspondingly more pronounced. The tension element is preferably designed as a cord or band, in particular braided or woven. In order to apply an adjustable tensile force by means of pretension, the cord or band optionally has a certain elasticity. A wire or a wire mesh can also be used as a tension element. In this way, largely conventionally available preliminary products can be used for the traction element, which facilitates the implementation of the heat shield brick with the traction element and also makes the use of it seem very interesting in terms of cost.

Advantageously, it is also possible to convert conventional heat shield bricks according to the new concept. The traction elements in the form of a cord or one

Tapes that are braided or woven, for example, can be easily applied to existing conventional heat shield stones.

In a preferred embodiment, the tension element consists of a ceramic material, in particular of a ceramic fiber material. Ceramic material is resistant to high temperatures and is resistant to oxidation and / or corrosion and is therefore ideally suited for use with a heat shield brick in a combustion chamber. Cords and / or tapes preferably consist of ceramic fibers which are suitable for use at up to 1200 ° C. The chemical composition of these fibers is, for example, 62% by weight of A1 ₂ 0 ₃ , 24% by weight of Si0 ₂ and 14% by weight of B ₂ 0 ₃ . The fibers are composed of a large number of individual filaments, the filaments having a diameter of approximately 10 to 12 μm. The maximum crystallite size for these ceramic fibers is typically 500 nm. The ceramic fiber material can be used to easily produce fabrics, knitted fabrics or braids of the desired size and thickness, or else cords or ribbons. With such a tension element ensures permanent securing of the heat shield brick even at very high operating temperatures, such as occur, for example, in a combustion chamber of a gas turbine.

The tension element is preferably at least partially glued to the heat shield brick. The glue provides additional securing of the tension element against a possible one. Removal achieved and durability increased accordingly. When gluing the tension element to the heat shield brick, both a conventional adhesive and a high-temperature-resistant adhesive can be used. Silicate-based adhesives can also be used, which have excellent adhesive properties and great temperature resistance. The use of ceramic or metallic materials for the tension element, in particular in the case of a ceramic cord or a ceramic tape, has proven to be particularly advantageous because this has a certain air permeability (porosity) due to the fabric structure, which means that the tension element is well connected to the Heat shield stone transported. The gluing is particularly effective if the configuration is selected with a circumferential groove in which a tension element engages. As a result, the adhesive can be let into the circumferential groove for gluing, as a result of which a particularly secure connection can be established. The adhesive can be introduced locally at various points in the circumferential groove or can partially or completely wet the circumferential groove, for example in the groove base. The traction element becomes, as it were, an integral part of the heat shield brick due to the gluing, the gluing being releasable or, if desired, non-releasable for a revision case.

The heat shield brick preferably consists of a ceramic base material, in particular of a refractory ceramic. By choosing a ceramic as the base material for the heat shield brick, the use of the heat shield brick is up to guaranteed very high temperatures, while at the same time oxidative and / or corrosive attacks, such as occur when the hot side of the heat shield brick is exposed to a hot medium, for example a hot gas, are largely harmless to the heat shield brick. Advantageously, the tension element can be easily connected to the ceramic base material of the heat shield brick. As already mentioned above, the fixed connection can also be designed as a releasable connection. In addition to the gluing, the attachment of the tension element by means of suitable fastening elements on the circumferential side, for example by means of a clamp or a screw connection, is also possible. By choosing a tension element, which at least partially consists of a ceramic material, a good adaptation to the ceramic base material of the

Heat shield stone achieved in terms of thermomechanical properties. Due to the fixed connection of the tension element to the base material, the heat shield brick is advantageously designed in a kind of composite with the tension element. This results in a compact design and structure of the heat shield brick, which has an extraordinarily high durability and passive safety even with high thermal and / or mechanical loads. This is a particularly great advantage when using the heat shield brick in a combustion chamber, because even after a crack or material tear, the heat shield function of the heat shield brick is still guaranteed, and in particular no fragments can get into the combustion chamber.

Economically, this results on the one hand in the advantage that in normal operation no extraordinary maintenance and / or revision of a combustion chamber having the heat shield brick is required. On the other hand, the heat shield stone is available in the event of special events

Emergency running properties so that consequential damage to a turbine, for example blading, can be avoided. The combustion chamber can be operated at least with the usual maintenance cycles, but it is also possible to extend the service life due to the increased passive safety with the pulling element.

The object directed to a combustion chamber is achieved according to the invention by a combustion chamber with an internal combustion chamber lining which has heat shield bricks according to the above statements.

The object directed to a gas turbine is achieved according to the invention 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 explanations for the

Heat shield block.

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

1 shows a perspective view of a

Heat shield stones with tension element,

2 shows a plan view of the hot side of the

1, FIG. 3 shows a perspective view of a heat shield brick modified compared to FIG. 1,

4 to 6 each show a view of a heat shield brick with a modified arrangement of the tension element compared to FIGS. 1 to 3,

7 shows a perspective view of a

Heat shield stones with circumferential groove, 8 and 9 each show a sectional view of a

Heat shield stones with variants regarding the circumferential groove,

10 shows an arrangement with two heat shield stones,

11 shows a plan view of an arrangement of

Heat shield stones on a supporting wall, and

12 shows a greatly simplified longitudinal section through a gas turbine.

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

1 shows a perspective view of a heat shield brick 1. The heat shield brick 1 has a hot side 3 and a wall side 5 opposite the hot side 3. A peripheral side 7 of the heat shield brick 1 adjoins the hot side 3 and the wall side 5. The peripheral side 7 has a peripheral side surface 9. The hot side 3 is acted upon by a hot medium, for example a hot gas, when the heat shield brick is used. On the circumferential side 7 of the heat shield brick 1, a tensile element 11 is provided which is prestressed in the circumferential direction. The tension element is prestressed in such a way that a compressive stress is generated normal to the peripheral side surface 9. In order to generate a prestress in the circumferential direction, the tension element can have a certain elasticity. With the tension element 11 is a significant increase in passive safety and thus

Durability of the heat shield brick 1 when used in a combustion chamber, for example in the combustion chamber of a gas turbine, is achieved.

As illustrated in FIG. 2, which shows a plan view of the heat shield brick shown in FIG. 1 on the hot side 3, the tension element 11 is over the full circumference _, the heat shield stone 1 attached to the circumferential side. By prestressing the tension element 11 in the circumferential direction, compressive forces S1, S2, S3, S4 are generated normal to the circumferential side surface 9. The compressive forces S1 to S4 are directed inward into the interior of the heat shield brick 1. In the present case, the heat shield brick 1 is cuboid, here designed with a square base. Due to the ring closure as a result of the arrangement of the tension element 11 over the entire circumference of the heat shield brick 1, a respective resulting compressive force S1 to S4 is generated on each side surface of the cuboid heat shield brick 1. As a result, the heat shield brick 1 is largely protected against the risk of crack formation or crack propagation on the hot side 3, the wall side 5 or the peripheral side 7. Due to the ring closure, one is particularly important

Material breakout prevents material from coming out of the heat shield brick 1. The durability of the heat shield brick 1 is thereby increased, so that a revision of the heat shield brick 1 is not necessary even in the case of a material breakdown, but the usual revision and maintenance cycles or longer intervals are achieved. In the event of a crack or collision, the heat shield brick 1 is secured by the pulling element 11, because possible fragments can only be removed from the composite of the heat shield brick 1 with a lot of work. The compressive forces S1 to S4 induced by the tension element 11 hold the heat shield brick 1 together permanently. The tension element 11 is in the present example of a band-shaped geometry. The tension element 11 can in particular be braided or woven.

FIG. 3 shows a perspective view of a heat shield brick 1, the heat shield brick 1 having a first tension element 11A and a second tension element 11B compared to the illustration in FIG. 1. The tension elements 11A, 11B are provided on the circumferential side 7 and are prestressed in the circumferential direction, so that a compressive stress is generated normal to the circumferential side surface 9. The first Traction element 11A is arranged on the end of the peripheral side 7 facing the hot side 3. The tension element 11B is arranged at the end of the peripheral side 7 assigned to the wall side 5. This double safety device with two pre-tensioned over the full circumference of the heat shield brick 1

Tension elements 11A, 11B can be safely avoided both in the area of the hot side 3 and in the area of the wall side 5 due to the compressive forces normal to the circumferential side surface 9 and possible breakage due to thermally induced cracking on the wall side 5 or the hot side 3 due to impact fracture.

FIGS. 4 to 6 show different views of a heat shield brick 1. 4 shows a first side view, FIG. 5 shows a second side view rotated by 90 °, while FIG. 6 shows a top view of the hot side 3 of the heat shield brick 1. Four tension elements 11A, 11B, 11C, HD are provided, which are each attached to the circumferential side 7 under prestress. Each of the tension elements HA to HD extends over three of the four side surfaces of the cuboid heat shield brick. The tension elements HA, HB are provided on the end of the peripheral side 7 facing the hot side 3. The tension elements HC, HD are arranged on the end of the peripheral side 7 facing the wall side 5. In its overall effect, the arrangement by the tension elements HA to HD results in a ring closure over the entire circumferential side surface 9 of the heat shield brick 1 (see FIG. 6), so that each of the four side surfaces forming the circumferential side 7 of the cuboid heat shield brick 1 has a compressive stress normal to the circumferential side surface 9 Experienced. With this configuration, a certain material saving can be achieved with the tension elements HA to HD, with almost the same securing effect against the risk of breakage as, for example, with the configuration shown in FIG. 3.

7 shows a perspective view of a heat shield brick 1 with respect to FIGS. 1 to 6 modified design. The heat shield brick 1 has a circumferential groove 13 on the circumferential side 7. The circumferential groove 13 is formed over the entire circumference of the heat shield brick 1. A tension element 11 engages in the circumferential groove 13. The tension element 11 in the circumferential groove 13 encloses the

Circumferential side surface 9 twice. It is also possible for the tension element 11 to enclose the peripheral side surface 9 several times, in particular three or four times (see FIGS. 8 to 10). The engagement of the tension element 11 in the circumferential groove 13 protects the tension element 11 in addition to increasing the passive safety of the heat shield brick 1. For example, when the heat shield brick 1 is used in a combustion chamber, direct action on the tension element 11 with a hot, corrosive or oxidative gas can be prevented by the engagement in the groove 13.

FIGS. 8 and 9 each show a sectional view of a heat shield brick 1. The heat shield brick 1 of FIG. 8 has a circumferential groove 13, while the heat shield brick 1 of FIG. 9 has a circumferential groove 13A and a further circumferential groove 13B. A respective tension element 11, HA, HB engages in the circumferential grooves 13, 13A, 13B. The tension elements HA, HB, HC enclose the peripheral side surface 9 several times. The tension element 11 in the circumferential groove 13 surrounds the circumferential sides 9 in triplicate (FIG 8), while the tension element HA encloses the circumferential side surface 9 in four and the tension element HB in three times. This multiple securing by means of tension elements 11, HA, HB ensures particularly effective protection of the heat shield brick during operation in the event of a risk of breakage, cracking or material rupture. The heat shield brick 1 here consists of a ceramic base material 19, in particular a refractory ceramic. The tension elements 11, HA, HB advantageously also consist of a ceramic material 15, for example a ceramic fiber material, which is braided in the form of a ribbon or cord or woven. This makes it possible to simply wrap the heat shield brick 1 with the tension elements 11, HA, HB by applying a certain pretension in the circumferential direction. The engagement of the tension elements 11, HA, HB in the respective circumferential groove 13, 13A, 13B at the same time secures the tension elements 11, HA, HB against loosening.

In addition to the cuboid geometry of the heat shield stones 1 shown, other prism-shaped geometries with a polygonal base area are also conceivable. The circumferential groove 13, 13A, 13B can also only partially enclose the circumferential side surface 9. The number and arrangement of circumferential grooves 13, 13A, 13B with tension elements 11, HA, HB engaging therein can be designed depending on the respective geometry and the load case of the heat shield brick 1.

FIG. 10 shows an arrangement with a heat shield brick 1 and a further heat shield brick 1A. The heat shield stones 1, 1A have a respective circumferential groove 13, 13A, in which a respective tension element 11, HA engages. To additionally secure the tension elements 11, HA, each of the tension elements 11, HA is at least partially glued to the respective heat shield block 1.1A by means of an adhesive 45. The adhesive 45 establishes a firm connection of the tension elements 11, HA with the heat shield stones 1.1A in the respective circumferential groove 13.13A.

The heat shield brick 1 and the further heat shield brick 1A are arranged to form a gap 35. The gap 35 is closed by the multiple arrangement of the tension elements 11, HA in the circumferential grooves 13, 13 A in such a way that a possible flow when the hot side 3 is acted on a hot medium, for example a hot gas, is largely prevented from an area facing the hot side 3 through the gap 35 to an area assigned to the wall side 5. By the tension elements 11, HA are in the arrangement with the Heat shield stone 1 and the further heat shield stone 1A protect them against an overflow of hot gas. In addition to this sealing effect, the heat shield stones 1, 1 A are restricted with respect to relative movements along a horizontal shock axis 47, shock absorption along the horizontal shock axis 47 being additionally achieved by the adjacent tension elements 11, HA of the respective heat shield stones 1, 1A in the area of the gap 35. This is of particular advantage when using the heat shield stones 1.1A in the combustion chamber of a gas turbine, where vibrations can occur as a result of combustion pulsations in the combustion chamber and there is a risk of an impact fracture.

The top view of an arrangement of a heat shield brick 1 and a further heat shield brick 1A is shown in FIG. 11 shows a support structure 21, for example a support wall, into which fastening grooves 33 are incorporated. The fastening grooves 33 extend along a groove axis 43 in the support structure 21. The heat shield brick 1 and the further heat shield brick 1A are fastened to the support structure 21 via respective fastening elements 23, the heat shield stones 1, 1A being arranged adjacent to one another along the groove axis 43. The top view in FIG. 11 shows a view of the heat shield stones 1.1A on the hot side 3, which is acted upon by a hot gas, for example a combustion gas, during operation. Each of the heat shield stones 1, 1 A has a respective tension element 11, HA. The tension elements 11, HA engage in a respective one

Circumferential groove 13, 13A of the heat shield stones 1.1A, a compressive stress being generated normal to the circumferential side surface 9. Such a support structure 21 with heat shield bricks 1.1A attached to it is used, for example, in the combustion chamber of a gas turbine. This will be briefly discussed below with reference to FIG. 12. 12 shows a gas turbine 27 in a highly schematic longitudinal section. The following are arranged in succession along a turbine axis 37: a compressor 39, a combustion chamber 25 and a turbine part 41. The combustion chamber 25 is lined with a combustion chamber lining 29 on the inside. The combustion chamber lining 29 comprises a combustion chamber wall 31, which at the same time has a support structure 21 (cf. also FIG. 11). The combustion chamber lining 29 further comprises heat shield stones 11, HA, HB which are fastened to the support structure 21. The heat shield stones 11, HA, HB are designed in accordance with the above statements. In operation of the gas turbine 27, the heat shield stones 11, HA, HB are acted upon by a hot medium M, in particular a hot gas. This leads to considerable thermal loads on the hot side 3 of the heat shield stones 11, HA, HB. Especially in the case of a gas turbine 27, there can also be considerable vibrations, for example due to combustion chamber hum. In the event of resonance, even sudden acoustic combustion chamber vibrations with large vibration amplitudes can occur. These vibrations lead to considerable stress on the combustion chamber lining 29 and the components encompassed by it, such as, for example, the support structure 21 and the heat shield bricks 1.1A, IB. The design of the heat shield bricks 1.1A, 1B with a respective pulling element H, HA, HB prevents the risk of breakage on the one hand and, on the other hand, ensures emergency operation in the event of breakage or crack formation, so that passive safety is clear compared to conventional heat shield bricks 1, 1A, 1B is increased. This results in the combustion chamber lining 29 being particularly insensitive to shocks or vibrations. The heat shield bricks 1.1A, 1B, which have a tension element 11, HA, HB, are both for exposure to the high temperatures of a hot medium M, for example up to 1400 ° C. in a gas turbine 29, and also for a high mechanical one

Energy input due to shocks and / or vibrations permanently resistant.

Claims

claims 1. heat shield brick (1.1A), in particular for lining a combustion chamber wall (31), with a hot side (3) which can be exposed to a hot medium (M), a wall side (5) opposite the hot side (3) and one on the hot side (3 ) and the wall side (5) adjacent peripheral side (7), which has a peripheral side surface (9), characterized in that on the peripheral side (7) a tensile element (11, HA, HB) is provided in the circumferential direction, a compressive stress (Sl , S2, S3, S4) is generated normal to the circumferential side surface. 2. Heat shield brick (1,1A) according to claim 1, so that the pulling element (11, HA, HB) extends at least in regions in the circumferential direction. 3. Heat shield brick according to claim 1 or 2, d a d u r c h g e k e n n z e i c h n e t that several tension elements (H, HA, HB) are provided. 4. heat shield brick (1,1A) according to claim 3, d a d u r c h g e k e n n z e i c h n e t that at least one tension element (11, HA) completely surrounds the peripheral side surface (9). 5. heat shield brick (1,1A) according to claim 4, d a d u r c h g e k e n n z e i c h n e t that the tension element (11, HA, HB) encloses the peripheral side surface several times. 6. heat shield brick (1,1A) according to one of the preceding claims, characterized in that the circumferential side (7) has a circumferential groove (13, 13A) into which a tension element (11, HA) engages. 7. heat shield brick (1,1A) according to claim 6, d a d u r c h g e k e n n z e i c h n e t that at least one further circumferential groove (13B) is provided, which is spaced from the circumferential groove (13A), wherein a tension element (HA) engages in the further circumferential groove (13B). 8. Heat shield brick (1,1A) according to one of the preceding claims, that the pulling element (11, HA, HB) is designed as a cord or band, in particular braided or woven. 9. Heat shield brick (1,1A) according to one of the preceding claims, that the pulling element (11, HA, HB) consists of a ceramic material (15), in particular of a ceramic fiber material. 10. Heat shield brick (1,1A) according to one of the preceding claims, that the pulling element is at least partially glued to the heat shield brick (1,1A). 11. Heat shield brick (1,1A) according to one of the preceding claims, characterized in that it consists of a ceramic base material (18), in particular of a refractory ceramic. 12. Combustion chamber (25) with an inner combustion chamber lining (29) which has heat shield bricks (1,1A) according to one of the preceding claims. 13. Gas turbine (27) with a combustion chamber (25) according to claim 12.