초록 ▼

The invention relates to a heat shield block, particularly for lining a combustion chamber wall, with a hot side that can be subjected to the action of hot medium and with a wall side situated opposite the hot side. A core area, which has a core material, extends inside the heat shield block from th

The invention relates to a heat shield block, particularly for lining a combustion chamber wall, with a hot side that can be subjected to the action of hot medium and with a wall side situated opposite the hot side. A core area, which has a core material, extends inside the heat shield block from the hot side to the wall side. The core area is surrounded by an edge area with an edge material whose heat conductivity is lower than that of the core material. This targeted thermal insulation in the edge area provided in the form of a material bond between the core material and the edge material renders the heat shield block particularly unsusceptible to the formation and growth of cracks in the core area on the hot side. The invention also relates to a combustion chamber provided with heat shield blocks of the aforementioned type, and to a gas turbine provided with a combustion chamber comprising such a heat shield block.

대표청구항 ▼

The invention claimed is: 1. A heat shield block for lining a combustion chamber wall, comprising: a hot surface exposed to a combustion gas; a wall surface arranged opposite the hot surface; a core portion comprising a core material and extending from the hot surface to the wall surface; and an ed

The invention claimed is: 1. A heat shield block for lining a combustion chamber wall, comprising: a hot surface exposed to a combustion gas; a wall surface arranged opposite the hot surface; a core portion comprising a core material and extending from the hot surface to the wall surface; and an edge portion comprising a porous edge material surrounding a circumference of the core portion, the thermal conductivity of the edge material determined by a pore size and density distribution of the edge material, the thermal conductivity of the edge material being less than the thermal conductivity of the core material, wherein a thermal conductivity of the core portion and a thermal conductivity of the edge portion are determined such that the core portion remains substantially free of thermal stresses during operation. 2. The heat shield block as claimed in claim 1, wherein the thermal conductivity of the edge material is less than 60% of the thermal conductivity of the core material. 3. The heat shield block as claimed in claim 1, wherein the thermal conductivity of the edge material is less than 50% of the thermal conductivity of the core material. 4. The heat shield block as claimed in claim 1, wherein the core material and the edge material are formed from the same ceramic material. 5. The heat shield block as claimed in claim 1, wherein the core material and the edge material are formed from a fireproof ceramic material. 6. The heat shield block as claimed in claim 1, wherein the core material and the edge material form a cohesive bond. 7. The heat shield block as claimed in claim 1, wherein the axial length of the edge portion is less than 20% of the entire axial length of the block along the hot surface. 8. The heat shield block as claimed in claim 1, wherein the axial length of the edge portion is between 5% and 10% of the entire axial length of the block along the hot surface. 9. The heat shield block as claimed in claim 1, wherein the edge portion extends from the hot surface to the wall surface. 10. The heat shield block as claimed in claim 1, wherein a peripheral surface adjacent to the hot surface and the wall surface is partially formed from the edge material. 11. A heat shield block for lining a combustion chamber wall, comprising: a three dimensional core portion, comprising: a core hot surface comprising a core material and exposed to a combustion gas, a core wall surface arranged opposite the core hot surface, a plurality of core peripheral surfaces arranged between an edge of the core hot surface and the core wall surface; and a three dimensional edge portion surrounding and enclosing an entirely of the peripheral surfaces of the core portion but not surrounding and enclosing the core hot surfaces and core wall surfaces, comprising: an outer hot surface comprising a porous material adapted for exposure to the hot medium, the outer hot surface coplanar and abutting with the core hot surface, an outer wall surface arranged opposite the outer hot surface, the outer wall surface coplanar and abutting with the core wall surface, a plurality of inner core peripheral surfaces in contact with the core peripheral surfaces and arranged between the edges of the outer hot surface and the core wall surface, wherein a thermal conductivity of the core portion and a thermal conductivity of the edge portion are selected such that the core portion remains substantially free of thermal stresses during operation. 12. The heat shield block as claimed in claim 11, wherein the thermal conductivity of the porous material is a function of a pore size distribution and a pore density distribution within the porous material. 13. The heat shield block as claimed in claim 11, wherein thermal conductivity of the porous material is less than 60% of the thermal conductivity of the core material. 14. The heat shield block as claimed in claim 11, wherein the core material and the porous material are formed from the same ceramic material. 15. The heat shield block as claimed in claim 11, wherein the axial length of the exterior portion is less than 20% of the entire axial length of the block along the surface exposed to the hot medium. 16. An annular combustion chamber for use in a gas turbine engine, comprising: a combustion chamber housing; a plurality of burners arranged peripherally around a turbine shaft of the engine and contained by the chamber housing; a combustion chamber wall formed on an interior side of the combustion chamber; an inner combustion chamber lining having a plurality of heat shield blocks comprising a block material having a core material and an edge material that surrounds throughout a circumference of the core material, the thermal conductivity of the edge material being less than 60% of the thermal conductivity of the core material as determined by a porosity of the core material and a porosity of the edge material such that the core material remains substantially free of thermal stresses during operation. 17. The annular combustion chamber as claimed in claim 16, wherein the core material and the edge material are formed from the same ceramic material.